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t~
~, M I N I S T R Y O F A V I A T I O N
~' A E R O N A U T I C A L RESEARCH C O U N C I L
REPORTS AND MEMORANDA
R. & M. No. 3223
Part I
TheLongitudinal Stability and Control of the Tandem-Rotor Helicopter
Part II
The Lateral Stability and Control of the Tandem-Rotor Helicopter
By A. R. S. BRAMWELL
L O N D O N : HER MAJESTY'S S T A T I O N E R Y O F F I C E
I96I
PRICE £2 0S. 0d. NET
Part I
The Longitudinal Stability and Control of the Tandem-Rotor Helicopter
B y A . R . S . B R A M W E L r .
COMMUNICATED BY THE DEPUTY CONTROLLER AIRCRAFT (RESEARCH AND DEVELOPMENT),
MINISTRY OF AVIATION
Reports and Memoranda No. 3223*
January, I96o
Summary. A siinple method of calculating downwash interference is presented and comparison of theoretical and flight test trim curves indicates that the method is reasonably accurate.
Since the stability of the tandem-rotor helicopter depends largely on small differences between the thrusts of the front and rear rotors it is necessary to calculate the rotor thrust derivatives far more accurately than for the single-rotor helicopter. More accurate expressions than those given in Ref. 8 have therefore been calculated.
The downwash interference causes a reversal of stick position with speed for part of the speed range with an associated divergence in the dynamic stability. This may be eliminated by choosing a suitable value of swash-plate dihedral angle. If, in addition, a suitable differential delta-three hinge angle is applied the tandem- rotor helicopter appears to be stable over the whole speed range except at hovering and very low speeds.
If the swash-plate dihedral is too small the normal acceleration curve, following a step input of control, flattens out and then increases again. Thus the tandem-rotor helicopter may satisfy the N.A.C.A. manoeuvr- ability criterion yet possess unsatisfactory response characteristics. It is suggested that the N.A.C.A. criterion is Unnecessary if stability of the short and long period modes is ensured. Again, a proper choice of swash-plate dihedral and differential delta-three hinge enables satisfactory control response characteristics to be obtained.
1. Introduction. The longitudinal stability of the tandem-rotor helicopter presents an easier problem to the helicopter designer than that of the single-rotor helicopter. It is well known that the single-rotor helicopter without tailplane or automatic means is inherently dynamically unstable. But when the lift of the aircraft is shared by more than one lifting surface, as in most fixed-wing aircraft or the multi-rotor helicopter, it is possible to arrange that the configuration is stable by suitably choosing the rates of change of pitching moment of the lifting surfaces, i.e. of the wing and tail combination of the fixed wing aircraft and front and rear rotor combination of the tandem-rotor helicopter. In the f ixed-wing aircraft this is achieved by correct choice of the C.G. position. In the tandem-rotor helicopter not only is C.G. movement available to control stability but there are also
the powerful effects of varying the angle between the rotor-hub axes (called swash-plate dihedral) and applying differential 33-hinges to front and rear rotors to control their lift-slopes.
e Previously issued as R.A.E. Report Naval 3 (A.R.C. 21,943).
(82028)
This report examines in detail the effects-of varying these parameters on the control to trim, dynamic stability and control response of a tandem-rotor helicopter having ,a configuration similar to the' Bristol 173. : ' ' . ~ , i . . :'
2. Estimation of Do~nwash Effect. ~ The, longitudinal stability and control of the tandem-rotor
helicopter depends almost entirely on small differences in the thrusts of the front and rear rotors. Since thrust depends greatly on the rotor inflow i t is eyident that a reasonably accurate estimate of the effect of the downwash of the front rotor on the rear rotor must be made before attempting the estimatio_n of the stability derivatives. Various forms of the, downwash pattern i n forward ̀ flight have been considered in the past, the most usual being a uniform cylindrical jet of air, e.g. Ref. 1, and the distribution due to a cylindrical vortex sheet, e.g. Ref. 2, but neither of these two patterns represents a precise physical description of the flow.
The idea of a cylindrical wake probably arose from Glauert's proposaP, that the induced velocity, assumed constant, at the rotor disc is the same as that of'a Wing of spin 2R carrying the same lift distributed elliptically across its span, i.el as give n by
T = 2rrR2pVvi o -- (1)
This expression is the same as would have been calculated if the thrust had been supposed due to the"increase of molrientum of a. cylindrical stream' of air whose cross-secti0nal area .on.. passing through the rotor is the same as the rotor'area and Whose velocity is increased from V before reaching the rotor to V + 2 v i o in the final wake, where v i 0 is a vector velocity in the opposite direction to the thrust. Such a physical picture is convenient as it is identical with that o f the slipstream of a hovering rotor, o r propeller and pr"ovides an easy way of calculating the induced velocity for a given thrust and forward speed for .V >>. vi. o (strictly speakingi f6r the momentum 'considerations, we should take the ftow velocity through the rotor disc .~/t all speeds as ( g 2 ÷~ vio~) 11~, which reverts to V at high speed,, as in equation (1), and v~0 at hovering).
.. An extensive series of wind tunnel tests ~ have shown, however, that the f low behind a lifting
rotor at forward speed is :very similar to that of a wing Of the same sPan and ,aspect ratio, i.e. the well known horse-shoe vortex system,, and indeed measurement of the induced velocity behind a rotor shows very good agree.ment with the calculated values behind such a wing.
As shown in Ref. 4,: and as predicfed for a circular wiiag in Ref. 5, the vortex' sheet in the vicinity of the rotor rolls up very rapidly and is almost completed at the rear edge of the rotor. Thus it can be said that in forward flight, the rear rotor of a tandem helicopter is completely immersed in the f low of a horse-shoe vortex system for values of/~ at least as low as 0. 095 which was the lowest value of/x in the tests of Ref. 4: Obviously, .between/z = 0 and/z = 0- 095 there is transition {:rom the propeller type slipstream at hovering to the line-vortex flow of forward flight but it is not known .exactly in what manner the chaflge takes place. It is likely that the flow due to the cylindrical vortex • sheet, of Ref. 2 would give satisfactory results for very low /z, say up to about 0.04, although, 'unfortunately, the lateral variation is given., on. ly for the plane through the .centre of t he (front) .rotor and judgment must be used to estimate the induced veloc!ty, at other positions behind the -rotor, the longitudinal distributions being used as a gnide; The line-vortex flow should be satisfactory ,for values of/z of 0.1 and above but the gap between/~ = 0.04 and/z = 0.1 will have to be 'faired in' graphically. Ref. 7 gives expressions for the induced velocity beh!nd a rotor based on the idea of the horse-shoe .vortex system and is intended for use at all speeds by.usinglan artificial expression for the circulation which reduces to zero in hovering and to a value which corresponds to the lifting
' ' " 2
wing at high speeds. However, a good deal of computation is necessary to find the induced velocity
at enough positions to give a good idea of the flow in the whole region of the rear rotor. What we
require is a suitable mean value of the induced velocity in this region so that it can be included as
part of the inflow ratio A and used in the familiar expression for thrust coefficient J
t c = C10o + c~,~ (2) where
and
a l ] B ( B ~ - B2t~2 + ~tz4) I . q = ~ B 2 + ,~tz 2
a B 2 B 2 _ ½t~ 2
c 2 - 4 " B ~ + ~1~ 2
This mean value can be Obtained from the measurements of Ref: 4 where it is seen that, except
in the region near the vortex cores, the induced velocity is fairly uniform laterally across the disc for
given longitudinal and vertical positions. Thus the lateral variation of induced velocity Could well be replaced by its arithmetic mean value. Now one would expect that the distribution of non-
dimensional induced velocity vi /v io relative to the axes of the vortices would be constant at all
speeds and the mean values of the lateral variation have been plotted relative to axes fixed, following
Ref. 2, so that the origin is at the centre of the rear rotor and the ~-axis lying parallel to a line
making an angle v i o /V (downwards) relative to the direction of flight, as shown in Fig. 3. This is
different from the orientation of the axes of Ref. 4 where the X / R - a x i s (corresponding to the ~-axis)
lies in the plane of the front rotor disc, that direction, of course, being arbitrary.
The values thus obtained are shown in Fig. 4 for the three longitudinal positions ~ = 1.07,
2.07 and 3.14 corresponding roughly to the front edge, centre and rear edge of a rear rotor. The
~-axis is not exactly parallelto the axis of the trailing vortices since in general the latter are curved
Slightly and it is for this reason that the curves shown in Fig. 4 are not symmetrical about the
= 0 axis. Thus for any given value of ~, which measures the distance of the particular part of the
rear rbtor above the trailing vortices, the value of v J r i o can be read off for the three values of ~ and the mean of these three values gives the mean interference velocity due to the front rotor.
The mean induced interference velocity at the rear rotor can now be expressed as
vi = k v i o (3)
Or if ~i = v~/~2R
kstc F f~ R = 2(t~ + ;~)~/2 (4 )
kstc F vi = 2(~2 + ~2)1/2 (5)
where tcF is the thrust coefficient of the front rotor.
.=, The effective downwash angle is taken as
:? kv~ o ' kstc F E - - - - - -
(82028) A*
(6)
The derivatives of e with respect to ~, @ and 00 are : , "
d~ k d~ i k~ i . . . . ! . . . . . .
d~ P d~ f72 ; '
k s Oa st~ f d[~ + I d A sto F (7)
- p 2 ( ~ + A~)~ 2 ( ~ + ~)~ ~ ~ - 2 ~ ( ~ + ~ ) l ~ j
de k s ~ ste~, dlz dA (8)
= P 2(~+ ~)1~ 2(~ + ~)3~ ~ + ~
d~ k 300 stcF dl~ ~ dh . (9)
• d00 - ~ z ( ~ + A~)I~ a(~2 + A~)3,2 ~ 0 +
In order to check, the above method of estimating the downwash effect wind tunnel tests are needed
of the loss of rear rotor thrust ' due to, the downwash of the front rotor. Unfortunately, no reliable tests are available but the pi tching moment of the helicopter, in the lower half of the speed range at least, depends almost entirely on, differential thrust changes (since pitching moments due to the
flapping will be comparatively small) so that comparisons of theoretical and measured tr im Curves should be a good test of the method. :These comparisons are made in the following section on the
stick position to trim. ., , . . . . . : -
3. Control Angle to Trim. 3~1. Derivation of Equatio n for Control Angle. The general layout of the tandem rotor helicopter is shown in Fig. 1 and the force and moment diagram in Fig. 2.
The reference line of the tandem-rotor helicopter is takep as the line which passes through the c.G.
and meets the rotor hub axes at equal angles ~r/2 - ¢, where 2~ is the angle between the rotor
hub axes (positive when the axes meet above the c.~.). The angle 2~ will be referred to as 'swash-
plate dihedral'.
I t is assumed that the movement of the stick applies the same amount of cyclic pitch to both
rotors, i.e. • B 1 = kl~q (10)
where kl is the gearing between stick and rotor-hub tilts. We also assume that a forward movement
of the stick, ~, reduces the collective pitch of the front rotor by k ~ / a n d increases the collective pitch
of the rear rotor by kz~ 7 so that 0 F = 00 - k2~ / =. (11)
a~/a oR = 00 + k ~ (12)
where kz is the gearing between the changes of stick angle and changes of collective pitch angle. The relative values of kt and k~ define what is known as the 'control mixture' in tandem-rotor
helicopters. Finally a tr immer will be added such that a tr immer movement of ~ increases the collective pitch
on the front rotor by k ~ and decreases the collective pitch on the rear rotor b y k ~ . We will then have
0~ = 00 + k ~ - k~ / (13) imd
OR = 00 k ~ + k ~ . 04)
4
Resolving forces horizontally
T• s i n (J~l - a l F - 0 - ¢ ) - + T R Sill ( B 1 -- a i r - - 0 + ¢ ) -- H B, c o s ( B 1 - a l / p - 0 - ¢ )
- H2~cos(B 1 - a l ~ - 0 + ¢ ) - D scos ro = 0. (15)
Resolving vertically
T • c o s ( B 1 - a l F - 0 - ¢) + T R c o s ( B 1 - a i R - 0 + ¢ ) + H F s i n ( B 1 - a l ~ - 0 - ¢ )
+ H ~ s i n ( B ~ - a , : e - 0 + ¢ ) - 1)] s i n y e - W = 0. (16)
and taking moments about the c.c.,
T F c o s ( B 1 - a l ~ - ¢ ) ( l f - h F t a n $ ) R - T R c o s ( B 1 - a i r + ~) (1 R - h R t a n ~ ) R
- r F s i n (B ~ - a~F - ¢ ) h F R - TR sin (B ~ - a~R - ~ ) h R R + H F s i n
(B 1 - a 1 / ~ - 4 ) ( I F - h F t a n c ) R
- HR sin (B 1 - a i r + ¢ ) ( l R - hRtan ¢ ) R + H~ cos (B 1 - alz~ - ¢ ) h E R
+ H R COB ( B 1 -- (/1R + ¢ ) h l ~ R + M] = O. (17)
This report assumes that the tandem-rotor helicopter has rotors of the same diameter, so that
after dividing by p s A ( f 2 R ) °~ and approximating for small angles equation (17) becomes
t c~ l F - t~Rl R - (t~Fh F -- t~RhR) ¢ -- t~Fhz~ (B1 - a~F - ¢) - tcRh R (B1 - a~R + ¢)
+ h o ~ ( B ~ - ~ 1 ~ - ¢ ) (l~, - h ~ ¢ ) - h ~ ( B ~ - ~ R + ¢ ) ( l ~ - h ~ ¢ )
+ hcFhF + h~nh R + 2C,,~i = O. (18) We will now write
t~ = qO o + c2A (2) and
a l = c~O o + QA (19) for each rotor, where
8 B~ ca - 3 B ~ + ~/z ~
and 2~
c~ - B~ + ,23_/z ~
The functions Q, c~, c a and Q are show~n in Fig. 48, plotted for a range o f /x and with B = 0-97.
I t will also be assumed that k o = l/x8 since the contribution of the in-plane rotor forces to the total
pitching moment should be very small in the tandem-rotor helicopter. Substituting in equations
(18) for t o and a~ and using equations (1), (13) and (14) we obtain
[c~ {0o - k~ (,/ - ~)}] l F + l~c~2~ - [c a {0 o - k s (~/ - ~}] k~¢ - hFcv~ , ¢
- [q {Oo + ~ (7 - ~)}]. z~ - ~c,,.~ + [q {Oo + ~ (7 - ~)}] ~ ¢ + hRc~;t~¢
- ~ [~ {Oo - ~ (7 - ~)} + ~ ] [~v - ~ {Oo - ~2 (7 - ~)} - ~ a ~ - ¢]
- ~ [ q {oo + ~ (7 - ~)} + c~Z~] [ ~ v - c~ {oo + ~ (7 - ~)} - c ~ + ¢ ]
+ hoF [k1~1
- hoR [k~n
+ hophF +
- c~ {eo - ks (v - ~)} - c~A:~ - ¢] ( z . - h ~ ¢ )
- c~ {eo + ks (7 - e ) } - c ~ R + ¢ ] ( z . - h R ¢ )
hoiff~R + 2C.,,~i = O.
5
(20)
(82028) A* 2
Equation (20) is a quadratic in ~/but it has been found from numerical calculations that most of the terms in the coefficients are very small, so that retaining only the important terms equation (20) can be written
AV 2 + B n + C = 0 (21)
where A = qk~k~ (h F - h~) + qc3k3 ~ (h F + hR)
B = -- c2k I (h.F,~tl~ + hR)t.l:d) -- Clk2 ( l B, + l~) -- ClklO 0 (hp, + hR)
- 2qc~&Oo (h~ - h~) - 2 q e ~ k ~ (h~, + h~)
c = qOo (l~,~ - l~) + c~ ( l~;~ - l~a~) + c~Oo ~ (h~ + h~)
+ (q~ + e~c~) (h~a~ + h ~ ) 0o + q& (l~ + l~)
+ q~.&0o (h~,~ - h~) ~ + 2C,~.
A typical solution of (21) gives a very large root, Which has no practical significance, and a small root which gives us the control angle we are seeking.
To a good approximation this latter root is given by
= - C / B , .
3.2. Calculation of Parameters for use hz Trim Equation and Stability Derivatives. The solution of the trim equations for the single-rotor helicopter corresponding to equations (15), (16) and (17) of this report is comparatively simple since the horizontal force equation is independent of the other two. Equations (15), (16) and (17) however are interdependent and require further equations relating A, ~9 and t~ and to solve them simultaneously would result in great complication. It is much simpler to represent t c and a 1 in terms of 00 and A and calculate the latter by approximate means.
Now for small angles and taking the level flightcase we can write equation (15) as
D~ + H= + H= = - {T~, No)= + T= (c~)=}.
If we assume H F = HR, this equation in non-dimensional form is
~ % + & = - ½ {tc~ ( . . ) ~ + to~ ( ~ ) ~ } .
The relation between the front and rear thrust coefficients can be expressed approximately as
and since toFIF = t~Rl~
tc~, + t~R = 2to'
7Now
and
to' {l~ ( ~ ) ~ + l~ (~)~}.
a~ = ~ - ( ~ ) ~ - (~i)~
(22)
(23)
(24)
(25)
(26)
(27)
The values of (Si)F and (~)= in equations (26) and (27) can be obtained from Fig. 50 using the
approximate values of tc~ and tc= from
2t~' l= tcF - l F + l=
and " '
'2t~' l F t~= = l ~ + l = •
Also ( c / ~ ] ) ~ , = ( c / n ~ ) = + 2 ¢
and o~n] ---- c~ O -- a 1
therefore (c/9) = = (c/D) = -- (a~)= + (a~) F + 2 ¢ .
Writing ( a l ) ~ = c~0~ + c~Z~
and (al)= = c80= + ceh=
(28)
and assuming the collective pitch is the same on both rotors
( a l ) ~ - (a l )= = c~ B ~ - ~ ) i.e.
(al)F - (al)R = ~ Q {(c/o)~ - (c/o)=}.- Q {(0,)~ - ($,)= - k (~0}.
But h is very close to unity so that approximately
(a~)~ - (a~)= -- 17 c~ {(c/p)~ - (c/o)=} + c~ (~,)=
therefore from equation (28) we obtain
2 ¢ + q @i)= (c/o)R = (c/o)F (29) 1 - Fc~
and substituting in equation (25) gives
(c/o)~ - ~d0 + & + l~ {2¢ + c~ @,)=} (30) t c' (l F + l=) (1 - 1~ q ) "
(ao) = can now be obtained by using equation (29) and then A) and A R from equations (26) and (27). Finally the mean collective pitch angle 00 can be obtained from
0 0 2t~' - c3 (AF + A~)
C 1
3.3. Comparison of Theoretical Trim Calculations with Flight Tests Results. Figs. 5(a) and 5(b) show the comparison between the theoretical level flight trim curves and some flight test measure- ments for two different helicopters. In Fig. 5(a) the theoretical curve would show much better agreement if it could be displaced downwards by about ½ deg. This may mean that the nominal t r immer setting in the flight tests was not in fact being achieved since there is no such disagreement in Fig. 5(b). Also, a fuselage pitching moment to account for this disagreement would have to be extremely large and beyond any reasonable value. Apart from this the agreement in both cases is quite good although the theoretical curves have, perhaps, too sharp a peak in the neighbourhood of
7
/x = 0-1. For this case the interference factor k (= vJV~o) was taken, from Fig: 4, as 1.5 and it may be that at such a low value of/ , , the values of k given by Fig. 4 are a little too large. For lower values of/z, k was estimated from the results of Ref. 2.
Since, as mentioned in Section 2, the trim curves depend very largely on the rotor downwash
effect, especially at the lower values of/z, the above comparisons.~ndicate that the present method
of calculating the downwash is reasonably accurate.
3.4. The Theoretical Tr im Curves for the Bristol 173 Configuration. Figs. 6 to 9 show the
effects of c.o. position and swash-plate dihedral on the trim curves of a helicopter similar to the
Bristol 173. When 6 = 0 deg there is a marked reversal of stick position with speed in the range/z = 0.1
to/z = 0.25 due to the powerful downwash effect. Also, in this range, there is a rapid divergence in
the dynamic stability. Increasing the swash-plate dihedral reduces the severity of the stick reversal
until at 6 = 3 deg th'e reversal is almost absent. Again, this is reflected in a marked improvement of the dynamic stability.
Movement of the centre of gravity seems to have little effect other than that of displacing the tr im curves vertically.
4. Equations o f Motion and Stabili ty Derivatives. 4.1. The Equations o f Motion. As in Ref. 8 wind axes are chosen for the stability axes and the assumption of no coupling between lateral and longitudinal motions is also made but we must now include the downwash lag terms M,~ and M~ which, for the tandem-rotor helicopter, are considerable, as will be shown in later sections. The derivatives X~, X~, Z~ and Z~ have been found to be extremely small and are omitted.
In order to render the equations of motion non-dimensional we use the same scheme as in Ref. 8
but divide the equations by a factor which includes the total disc area, i.e. if d is the area of one rotor we divide the force equations by 2psA(f~R) 2 and the moment equation by 2psd( f2R)ZR and the non-dimensional form of the equations of motion is
da
d~-
d~ - z~¢~ +
d~
where
x~ dO - - -- xuu -- XwW + tc~O COS Te
1~2 dr
- zwv3 + t c ' O s i n T e - 17+ ~
d~ d~O dO + J f u + X ~ + oJ~ + ~ + Vd.c
x,j~ + xooO o (31)
= z ~ + zooO o ( 3 2 )
_ kc~m~ tz~mo o ( 3 3 )
i + % : 2 -
m,~ /z2mu . m~ - ' - i B ' x - i B
Ix~m w mq ~o - a n d v -
Solving the above equations by the usual substitution ~ = Uo ea~, etc. and putting
x~l = Xoo = z~ = zoo = m~ I = moo = 0
gives the frequency equation for disturbed motion
A A 4 + BA 3 + CA ~ + DA + E = 0
where
and : " " " , : : - ..:-!:_
B = N + v + . x ( z +
C = P + N v + Q x + ~ o 1~+ Sfl
D = Pv + R X + Qo~ - S # g - f l T
E = R~o - Td/ f
N = - x ~ - z w
P = x u z w - XwZ,u
" : " " - " ' " - Q = - - l g + x ~ - t c sinye + z , ~ - - / *2
R = - t e' (z= cos Ye - x,~ sin ye)
... . ' S = t c c o s y ~ - x w ~ + + z w - - ~2
T = - t o' (z~ cos Ye - xw sin Ye).
Usually the terms zJF= and xq/iz= and products involving them are,negligibly small.
(34)
(35)
(36) (37)
(38) (39)
(40)
(41)
(42)
(43)
4.2. Calculation o f Rotor Derivatives. 4.2.1. Derivatives o f t, and a 1 wi th respect to ~, ~ and 0 o.
Since the, pitching moment of the tandem-rotor helicopter depends mainly on the difference in
t h r u s t b e t w e e n front and rear rotor it is necessary to calculate very accurately (e.g. to at least four significant figures) the thrust derivatives of each rotor. The approximate ~expressions and values given in the graphs of Ref. 8 for the thrust derivatives are not accurate enough for tandem rotor work. The derivatives of the basic relations between t,, ax and ~D have therefore been recalculated without making approximations except, perhaps, in the final form when known to be satisfactory for the tandem rotor work. These calculations are made in Appendix 1 and the approximate results given
again below. They are .~
/ )~st~ t O t o _ + I Cl'00 + c(~ ] t l - 2 ( ~ 2 + ~,~)sI2/ ... . (44)
~a~ c~ ~D + 2(~2 + ~,~)~I25 + cs'Oo + c~'A 1 2(t~e + Az)a/z + 2(t~2 + A2)1/2t ( 4 5 )
'~ :-.. Oa 1 c4
7:~ Ot o cl
: : , ,, O0 o
C a • . . . ~ ,
A
1
9
(46)
(47)
~48)
where
Oa~ ca 1 - 2(t~ 2 + h~)312 t + 2(/,z + ~)~!~ qQ - c~c3 00--~ = A (49)
A = I - )~st e c2s 2(~2 + a2)3/2 + 2(/~ ~ + a2/~;~ c , ~ . (50)
. r
Equations (44), (46) and (48) should be used as they stand for the front rotor only. Expressions for the rear rotor thrust derivatives must include corrections for the downwash interference which appears as a change of rotor incidence.
If the suffices F and R denote the values of the derivatives of front and rear rotors as calculated
from equations (44), (46) and (48) and if the suffix RD denotes the value of the rear-rotor derivative corrected for downwash interference, we have
since in this case the values of
-,oo .l ~ ] R and \0v3]~ are almost exactly the same.
(51)
(52)
= - dgo (53)
4.2.2. Rotor derivatives with respect to q. The usual method of calculating the rate of pitch
derivatives in previous stability work, e.g. Ref. 8, has been to use the results of Ref. 9. It is claimed
in Ref. 10, however, that these results do not compare well with flight tests and a more detailed analysis is given there which gives better agreement. A similar analysis, but using the notation and
system of axes of this report and giving also the roll derivatives, is presented in Appendix 2. The result for m~ is
~4ah l§BOo + ~h_½t~al I (54) (mq) r = 7(B g _~ ½/z2)
The xq derivative is usually negligibly small and zq = 0.
4.2.3. Effect of 83-hinge on rotor thrust derivatives. It will be seen in a later section that the front rotor downwash causes severe instability with incidence, i.e. m w becomes large and positive. A method of achieving a negative m~o on the tandem-rotor helicopter is to provide differential 88-hinges for the rotor blades--negative on the front rotor and positive on the rear, where a negative 8a-hinge is one in which the blade angle decreases with increase in flapping angle. This has the
effect of decreasing the lift slope of the front rotor and increasing that of the rear, thereby providing a powerful nose-down pitching moment with incidence. The calculation of ~t~/~ for a rotor
10
with a 33-hifige is given in Appendix 3 and shows that if Oto/SZ~ is the value of the lift slope of a rotor without a 8a-hinge, then the corresponding value with the 38-hinge (Ote/8~)s ~ is
\07~1~ 8 - ~ 1 + 6c3 - ~ ) (55)
where the positive sign refers to a positive 83-hinge and vice-versa.
4.3. Comple te Hel icopter Derivat ives .
where
The expressions for the force derivatives are
xu = (xu)F + (xu)= + (:@
+ _
~ u ] ~ + \ ~ u l ~ t J
O o
do . - 104ps2A
I I
- - and \ ~ - ] F = \ 0u ]i2 = 7~ approximately.
(56)
The total derivatives of rotor force with respect to rate of pitch are very small and are not wortl~ including but the separate components must be found in order to calculate the moment derivatives.
(59)
the h c terms being very small
zu = - ½ i \ ~ u ] ~ " + k~u]~D} ( 5 8 )
Thus ~ = (~)~ + (~)~ = { ( ~ h ~ ) ~ - ( ~ j ~ ) ~ } + ( (~,ol~)~ - ( x & ) ~ }
and ~ = (~)~ + (~)~ = {(~.~h~)~ - (~,ol~)~} + { (~wl~)~ - ( ~ u h ~ ) ~ } .
The moment derivatives are then
m u = - ( z u l l ) ~ - ( x u h l ) ~ + ( z J 1 ) ~ - (x~h~)~
m w = _ (zwll) ~, - (xwhl) F + (zwl~)i~ - (xwha) R
m a = - ( Z q l l ) F - (xqhl) F -t- (Zqll) R - (xqha)R + (ma)r
where (mq) r is the moment due to rotor tilt given by equation (54) and
hlF = h Fcos(% + ¢) + l F s i n a s--- h F + lF%
h~;~ = hR cos (% - ¢) - lR sin % = hR -- lR%
: l ~ = l~ cos,-8 -- hF sin (% + ¢) " l~ -- h~ (% + 'k)
lli~ = IR cos a s + hR sin (~ - ¢ ) ___ li~ -- hR ( % - ¢).
11
(60)
(61) , i
(62)
(63)
(64)
(65) (66) (67)
( 6 8 )
4.4. Derivatives due to Downwash Lag. . 4.4.1. Lag in change of incidence. Let e be the mean downwash angle at the rear rotor and ~ the change ;of helicopter incidence. The distance betw~een the rotor centres is (l F + IR)R and we will treat this as the significant distance between the rotors although the downwash pattern in this region is by no means well defined. The time taken to traverse this distance is (l~ + l~)R/V and the downwash angle at the rear rotor is therefore
de r & (t~ e = - ~ L ~ - d t
The incidence ~' at the rear rotor is
N o w
therefore
o r
and
V -/R)R] . " (69)
. , " h ~ t
.~J1 *
dt V
_ dt
& & (l~ + l~)R da dt V
de) & ~ (z~ + Z~)R ~ ' = a 1 - ~ / ~ + ~ V
.
so that
i.e.
de) de ~ . . . . : w ' = v ~ 1 - N + U ~ ' P (IF +119R
(70)
" " , ] : j : ' ..'.7:,,
I ( de) ded~ (l~,+ lR)l iRR d M = (Zw) Rw'IRR = Z w Va 1 - ~ +-d~x
M~ = (Z~)R -Ud = (zw)R G v
de (71)
The derivatives x , and z , can, of course, be calculated but they are negligibly small.
4.4.2. Lag 'due to change of forward speed. speed is
e = ~ u u dt -- and " , -
du k dt V J
Thus, in a similar manner to that of 4.4.1
-The change of downwash due to change of forward
(72)
4- ~ ~, % '
de m~ = (zw)R(l ~ + IR)I ~-d~. (73)
Again the force derivatives with respect tO ~ are negligible. I t is interestiiag to note that derivative
m~ does not appear in fixed-wing aircraft calculations as de/d~t is zero. ,
12
5. Discussion of Derivatives. 5.1. Force Derivatives. The force derivatives are shown in Figs. 12 to 15. The variations of the total derivatives due to changes of ~ and c.c. position are negligible
since the changes of front rotor derivatives are cancelled by opposite changes on the rear rotor. The variations of the derivatives with tip-speed ratio tz are thus very similar to those/of the
single-rotor helicopter. These variations have been fully discussed in Ref. 8 and so will not be
repeated here.
5.2. Moment Derivatives.
5.2.1. v -=
The variation of v with/x is shown in Fig. 16. The contribution due to precession of the rotor
discs (which is the only source of rotor damping in the single rotor helicopter) is also shown and is seen to be small and, except in hovering, may even be considered negligible. The large damping in pitch of the tandem-rotor helicopter is due, of course, to the fact that a steady rate of pitch increases the rear rotor incidence and decreases the front rotor incidence thus providing a large
nose-down pitching moment.
5.2.2. Yf (---- t~2. mu]zB !
The variation of Y{ with/z is shown in Fig. 17. It will be seen that there are three effects:
(a) large variations with/~ due to downwash changes
(b) large variations with q~
(c) mainly small variations with c.c. position.
In considering (a), we assume that the downwash effect is zero at hovering and rises to a maximum at about/~ = 0.1. The downwash effect with 'forward speed above t~ = 0.1 is determined from
equation (7) of Section 2. The three terms of equation (7) can be recognised as (i) the change of
induced velocity due to change of thrust and (ii) and (iii) as the change in downwash angle due to change of induced velocity at constant forward speed and change of forward speed with constant
induced velocity. The first term (i) is usually small. The last two terms can be shown to be of equal sign and magnitude for/~ >~ A, and represent a decrease of downwash angle with forward speed. Thus when t~ .4 A the downwash always causes a nose-down pitching moment with increase of
forward speed, the effect being most severe at about/~ = 0.1. In (b), variations of ~ alter the incidences of front and rear rotors and it can be seen from equation
(44) of Section 4.2.1 that in general the derivatives of thrust with respect to forward speed of front and rear rotors will be different. If ~ is positive the front rotor will have a larger thrust derivative than the rear one and this will provide a nose-up pitching moment with speed. A given value of
will provide a contribution to Yf which is roughly constant over the lower part of the speed range (see Fig. 17), whereas the destabilizing effect of the downwash varies considerably in this range. The value of ~ required to eliminate the downwash effect is probably about 5 deg for the type chosen and with central C.G. position. However, this value may then be too large for the hovering case, where the downwash effect is absent, and would lead to a rapidly divergent oscillation similar to that of the single-rotor helicopter. The same effect may also appear at high speeds where the downwash
effect is small.
13
It would be desirable, therefore, to have means of varying ~ in flight in order to have the optimum, or at least a suitable, value of Jg' at any given speed. This could be achieved, for example, by a trimmer which moves the front and rear swash-plates in opposite directions. The trimmer could be calibrated in terms of forward speed so that the pilot could select the appropriate value of g/g" for the speed at which he wished to cruise.
Whether or not it is worth providing such a trimmer depends on the designer's opinions as to the seriousness of the instability and the complexity of the other flying controls.
5.2.3. ~o(-- tz~m*°] iB/
Fig. 18 shows the variation of ~o with/~ for zero 38-hinge for different values of ¢ and C.G. position.
It will be seen that the effect of ¢ on oJ is smaller. For the tandem-rotor helicopter the longitudinal
cyclic pitch B 1 does not cancel the backward flapping al , in fact at high speeds a 1 may be several times larger than B1, and the rotor force vectors are then tiked backwards in trimmed flight and
cause a destabilizing nose-up pitching moment when the incidence is increased. This effect gets worse with increase of speed as shown in the case of ¢ = 0. Increasing ¢ changes the moment arms of the force vectors in the stabilizing sense as shown by the case ¢ = 3 deg.
The effect of C.G. position on ~o is very marked. The downwash effect reduces the thrust derivative on the rear rotor tending to result in a destabilizing nose-up moment With incidence. This destabiliz- ing moment can be reduced, of course, by setting the C.G. forward, the moment being directly proportional to C.G. position. The downwash effect can be seen in the peaks of the curves in the region of/~ = 0.1.
Fig. 19 shows how a $3-hinge affects the case ¢ = 0 and C.G. position central. It is seen that oJ, even for this 'worst case' ,can be completely shifted into the stable region for a reasonable value of C.
m~ m~b 524 )aodx( )
The variations with/z of the downwash lag derivatives/3 and X are shown in Figs. 20 and 21.
The curves were calculated from equations (7), (8), (71) and (73) for t~ = 0.1 to tz = 0.4 and faired in for the region/z = 0 to/~ = 0.1 on the assumption that the derivatives are zero at/~ = 0. T h e Slight variations with c.~. position are due to the variations in length of moment arm and strength 0f downwash from the front rotor.
6. Discussion of Stick-Fixed Dynamic Stability. 6.1. Effect of C.G. Position and Swash-Plate Dihedral. 6.1.1. Stability in hovering.
The dynamic stability in hovering of the tandem-rotor helicopter, as can be seen from Figs. 22(b) and 22(c), is independent of C.G. position and varies only with the 'dihedral' angle of the rotor-hub axes, 2~. In fact, as with the single-rotor helicopter, stability of the tandem helicopter in hovering depends almost entirely on m~ and ma; both m~ and m e are unaffected in hovering by C.G. position but m u is directly proportional to ~. If m u is positive there is a divergent oscillation, which becomes more divergent and whose period becomes shorter as m~ is increased.
On the tandem helicopter it is possible to reduce mu to zero by tilting the rotor-hub axes outwards (i.e. ~ becomes negative) so that the positive contribution to m~ from the rotor tilt derivatives is
14
balanced by a negative contribution from the thrust derivatives. This can be expressed by
In hovering
[Saq {Sto] ?to] te~'hF \-O-(tt ]~, + t"Rh~ + IF - IR = O. (74)
(sto c2(% + ¢) { to] c2(% - ¢) \ a JF = A ; \ S ]R =
Inserting typical values for the Bristol 173 into equation (74) gives ~ = - 1.3 deg, i.e. when the rotor-hub axes are tilted outwards and make an angle of 2.6 deg to one another m,~ is zero and the helicopter is neutrally stable. If m u is negative there is a pure divergence and, as with the single-rotor helicopter, it is impossible to obtain dynamic stability with m u and m a alone.
6.1.2. Stabili ty a t / z = 0.1. It will be seen from Figs. 23(a) and 23(b) that at about/~ = 0.1 the stick-fixed motion of the tandem helicopter is rapidly divergent for all the cases considered, the motion doubling its amplitude in about 2½ seconds. In these cases the constant term E, which is
proportional to m~z~ - muzw, is negative since the m u term is positive because of the powerful
downwash effect, as explained in Section 5.2.2. The rotor-hub dihedral necessary to make the m~
term negative would be about 16 deg (¢ = 8 deg) and this may be an excessive value in practice.
The mw term, which is much smaller, also acts in the destabilizing sense due to the downwash effect
and it can be seen from Fig. 23(b) that the variations in mw due to C.G. movement are too small to
have much effect. It appears, then, that at speeds in the region of/~ = 0.1 the tandem-rotor helicopter, except
perhaps with 3~-hinges, will suffer from a purely divergent instability.
6.1.3. Stability above/~ = 0.1. As the trimmed speed increases above t~ :- 0.1 the downwash
effect on the stability diminishes rapidly and it can be seenfrom Figs. 24(b), 25(b) and 26(b) that the purely divergent motion occurs only for ¢ < 2 deg at/~ = 0.2 and for ¢ < 1 deg for/~ = 0.3 and 0.4. Forward movement of the C.G. also becomes more effective in improving the stability and it can be seen that with the correct combination of ~b and C.G. position it is possible to make the helicopter dynamically stable.
6.2. Effect of 38-hinge. It will be recalled from Section 4.1.3 that the fitting of 3~-hinges enables the derivative m w to be varied over a wide range and the effect on the dynamic stability of varying the 83-hinge angle is shown in Figs. 27 to 30. In hovering there is no coupling between the vertical motion and the fore-and-aft and pitching motion so that the 38-hinge has no effect on the stability.
At /~ = 0-1, as can be seen from Fig. 27, the 83-hinge effect alleviates the strong divergence although increasing the value of C beyond 0.15 has no further effect. However, it appears that a much smaller value of C--about 4 deg instead of 8 deg without 38-hinges--can now be used to obtain positive stability and this value may be acceptable.
For/z -- 0.2 and above Figs. 28 to 30 (C.G. back) show that the 38-hinge greatly improves the stability but again there is little further improvement when C exceeds 0.15.
The problem, which occurs with the single-rotor helicopter, of introducing a pure divergence by
having too great a value of m~o at the higher speeds (where z~ is positive) need not arise with the tandem-rotor helicopter since the static stability can always be made positive by choosing a suitable
value of m~ by varying ¢.
15
6.3. Effect of Downwash Lag on the Stability. Th e effect of downwash lag on the stability has
been calculated for two cases a t /z = 0.1 (where the derivatives are largest) and the results given
below.
X and/3 included
X omitted
/3 omitted
X and ~ omitted
q~ = 0 ° C.G. Central q~ = 3 ° C.G. Forward
r = 0.332 sec - t
r = 0.343 sec -1
r = 0.418 sec -1
r = 0-431 sec -1
r = 0.233 sec -1
r = 0"252 sec -1
r = 0.311sec -1
r = 0.342 sec -1
i t will be seen that both derivatives improve the stability, the lag due to forward acceleration having
the greater effect.
7. Discussion of Control Response. Figs. 31 to 46 show the t ime histories of the response of the
tandem-rotor helicopter to a sudden 1 deg backward displacement of the stick. A peculiarity of
tandem-rotor helicopter response can be seen in many of the normal acceleration-time curves.
In Fig. 31, for example, the slope of the curve increases up to about t = 1 sec, then decreases slightly
up to about t = 3 secs and then increases again. This cannot be regarded as a satisfactory response
because the normal acceleration never 'settles down ' ; nevertheless the curve satisfies the N.A.C.A.
manoeuvrabili ty criterion s, since d2n/dt ~ < 0 before t = 2 secs. T h e reason for this shape of curve
• is that there is large damping in pitch (large mq) which damps the motion in its early stages, but as
speed increases the divergent m** effect predominates and causes the acceleration to ' run away'.
Thus , satisfaction of the N.A.C.A. criterion does not necessarily indicate acceptable manoeuvrabili ty
for the tandem-rotor helicopter. T h e N.A.C.A. criterion was devised from measurements of the
normal acceleration of the single-rotor helicopter where m u usually has a small positive value and
where there is no purely divergent mode. In this case (and also for the subsonic fixed-wing aircraft
case) the condition d~n/dt ~ < 0 is all that is required to ensure that the normal acceleration curve is
satisfactory. A typical curve for the latter case is shown in Fig. 47 together with the desirable
response curve and a typical curve for the tandem-rotor helicopter. I t is clear that the N.A.C.A.
criterion, which is intended to describe an acceptable response curve, is not detailed enough to
cater for the case of the tandem-rotor helicopter. I t is difficult to express a satisfactory response
curve in words but since the response is determined by the dynamic stability satisfactory response
will certainly occur if there is good damping of the short period mode and if the long period mode
is no worse than slowly divergent. Thus for the single-rotor helicopter a tailplane strongly damps the
short period mode and improves the long period mode so that even if the latter is still unstable
the manoeuvre will have been completed before its amplitude begins to increase rapidly. T h e
tandem-rotor helicopter has adequate damping in pitch but if the swash-plate dihedral is too small
the latter part of the manoeuvre will be divergent. T o ensure satisfactory response requires that the
stability associated with speed changes must not be rapidly divergent. A slow divergence or slowly
divergent oscillation is permissible since the effect of the speed changes will not be felt much before
the manoeuvre is over.
16
Another peculiarity of helicopter control response, described in Ref. 13, is the sudden change of • normal acceleration with sudden stick movements: On the single-rotor helicopter this is followed
by an unpleasant pause in the increase of acceleration in a pull-out and its severity is determined by the ratio of rotor thrust change to rotor pitching moment with stick movement. In this case, the ratio can be varied only between narrow limits but on the tandem-rotor helicopter it can be varied arbitrarily through the control 'mixture' (Section 3.1) since differential collective pitch supplies a moment without a change of total thrust. For typical control mixtures the force-moment ratio is much smaller than values for the single-rotor helicopter and the pause in normal acceleration, although clearly seen in Figs. 31 to 46, should barely be noticeable in practice.
Forward movement of the e.G. improves the response but is more effective when associated with values of ¢ > 0.
The effect on the control response of fitting Ss-hinges is shown in Figs. 39 to 46. It can be seen that although the response is considerably improved for the case ¢ = 0 deg it is seldom satisfactory at any speed even for the largest 88-hinge angles. However, when ¢ = 3 deg the response is well damped in nearly every case.
: 8. Conclusions. 8.1. Reasonably accurate estimates of the front rotor's downwash effect can be made from the wind-tunnel measurements of Ref. 4 for/z > 0.1 and from Ref. 2 for/~ < 0.05. The relevant measurements from Ref. 4 are represented in Fig. 4 of this report. These estimates can
be checked by comparing theoretical trim curves with those measured in flight. Agreement is
quite good. -
8.2. The trim curves show a stick reversal with speed between/~ = 0.1 and /z = 0.25 for ¢ = 0 deg. Increasing ¢ reduces the stick reversal and eliminates it when ¢ is about 5 deg.
8.3. In hovering the tandem-rotor helicopter has a divergent long period oscillation whose rate of divergence and frequency of oscillation increases with ¢. When ¢ is about - 1.3 deg (for a helicopter similar to the Bristol 173) m~ is zero and the motion is neutrally stable but it is impossible to make the helicopter positively stable.
8.4. At about/z = 0.1 and for a certain range above this value (depending on ¢) there is a rapidly divergent stability mode associated with the stick reversal of 8.2, i.e. negative rn u. Increasing ¢ improves the stability and when ¢ = 5 deg rn~ is positive at all speeds but there may then be a divergent oscillation if the e.G. is not fully forward {(/• ~ lF)/(1R + lr) = 0-1}.
8.5. Differential Sa-hinges greatly improve the stability and by a correct choice of swash-plate dihedral and ~3-hinge angle the helicopter may be made positively stable at all speeds except hovering. It appears that there is little further improvement when C exceeds about 0.15.
8.6. The control response is unsatisfactory if there is a p.ure divergence, unless i t i s fairly slow, since although there is large damping i n pitch the normal acceleration 'runs away' before the manoeuvre is over. In fact it is possible f0r the helicopter to satisfy the N.A.C.A. divergence requirement yet still possess unsatisfactory response. Again, a suitable choice of ~a-hinge angle and swash-plate dihedral can be made to provide satisfactory control response.
. . . : -
i7
a
a0
a I
al s
A
A
A
A1
b
bl
b l s
B
: B
B
B
B1 C
C
: c ;
C
C
C~
Cv
• L IST O F SYMBOLS -
Lift slope of blade section. (Taken in this report as 5.6)
Coning angle of rotor blades
Angle between tip-path plane and plane perpendicular to no-feathering axis. Positive for backward tilt of disc !
Angle between tip-path plane and plane perpendicular to rotor hub axis. Positive for backward tilt of disc
Area of one rotor disc
Coefficient of ~7~ in trim quadratic
Angular velocity vector of blade
Lateral cyclic pitch application
Number of blades
Lateral tilt of rotor disc relative tono-feathering axis. Positive when disc tilts towards advancing blade
Lateral tilt of rotor disc relative to rotor hub axis. Positive when disc tilts towards advancing blade
Tip-loss factor. (Taken in this report as 0.97)
Coefficient of 2, 8 in stability quartic
Moment of inertia of helicopter about lateral axis, slugs ft 2
Coefficient of ~1 in trim equation
Longitudinal cyclic pitch application
Blade chord ft
Rate of change of blade pitch with flapping (see equation (131)of Appendix 3 on ~8,hinge)
See equation (2)
See equation (19)
dC1 dC4 - - . , o o
Constant term in trim quadratic
Coefficient of ~2 in stability quartic
L 2psA(~R) ~
rolling-moment coefficient
Y 2psA(~R) 2
side-force coefficient
18
Oral
D
DI
Do
do
E
hR
hlR
H
hc
H
i,j,k
Ii
k 1
L
L
M
M.~, M w etc.
mu, m w etc.
M1
P
L I S T OF SYMBOLS--c6ntinued
MI 2psA(~)R)~R
Coefficient of h in stability quartic
Drag of fuselage ib
Drag of fuselage at 100 if/see
Do l O~ps2A
Constant term in stability quartic
See Fig. 1
See Fig. 2
Component of rotor force parallel to tip-path plane lb
H
Angular momentum vector of blade
Set of perpendicular unit vectors; i lies in the plane of blade flapping and k is paratlel to the rotor hub axis
B dimensionless form of pitching moment of inertia WR2/g
Moment of inertia of blade about flapping hinge, slugs ft ~
vjvi o, ratio of inddced velocity at a point in the induced velocity field to the momentum velocity
Ratio of longitudinal cyclic pitch.angle to stick angle, see equation (10)
Ratio of differential collective pitch angle to stick angle. See equations (i1) and (12)
Lift of a blade, lb
Rolling moment, lb ft. Positive when it tends to roll helicopter to starboard
P!tching moment, lb ft. Positive in nose up sense
Moment derivatives OM/~u, OM/Ow etc.
Dimensionless moment derivatives
Fuselage pitching moment lb f t
Increment Of normal acceleration in g-units
Rate of roll, angular velocity about longitudinal axis, positive when to starboard
Rate of pitch, angular velocity about lateral axis, positive in nose-up sense
19
L I S T OF S Y M B O L S - - c o n t i n u e d
X
X
Xu, xw etc.
xu, x w etc.
Y
Z
z ,zw
Zu, z~ etc.
r Distance of blade element from axis of rotation, ft
r Real part of root of stability quartic
R Rotor radius, ft
bc s ~r--R solidity of rotor
T Rotor-force component perpendicular to tip-path plane
T t , =
[sA(~2R) 2
W tO ? ----_
2psA(~R) 2
u Increment of velocity along flight path, ft/sec
U - ~ R ' dimensionless form of u
Up Component of relative wind perpendicular to bladel ft/sec
U T Component of relative wind parallel to blade chord, ff/sec
V Tr immed speed of helicopter, ft/sec
V - f ~ R ' dimensionless form of V
v i Induced velocity, ft/sec
vi0 Induced velocity at rotor disc as calculated from momentum theory,
ft/sec
^ vl dimensionless form of v~ vi - f2R '
w Increment of velocity perpendicular to flight path, ft/sec, positive
downwards
gO = Y~R ' dimensionless form of gO
= r/R, fraction of blade radius
Component of force parallel to x-axis (wind axes)
Force derivatives ~X/~u, ~X/~w etc.
Dimensionless form of X~, X ~ etc.
Component of force parallel to y-axis (wind axes)
Component of force parallel to z-axis (wind axes)
Force derivatives ~Z/~u, ~Z/~w etc.
Dimensionless form of Zu, Z w etc.
20
o~ D
o~ n f
(Z 3
O~
7e
A
6
~ , v , ~
oo
LIST OF SYMBOLS--continued
Incidence of rotor disc, angle between relative wind and tip-path plane, positive for backward tilt of disc
Incidence of no-feathering axis, angle between plane perpendicular to no-feathering axis and relative wind. Positive for backward tilt
Incidence of helicopter, angle between flight path and reference line of helicopter. Reference line defined in Section 3.1. Positive when nose up
Incremental change of %
Change of incidence of rear rotor
Blade flapping anglerelative to plane perpendicular to no-feathering axis
Blade flapping angle relative to plane perpendicular to rotor-hub axis
Lock's inertia number, pacR4 /1
Angle between horizon and trimmed flight path. Positive when aircraft climbing
Blade profile drag coefficient. (Taken in this report as 0. 016)
Defined in equation (50)
Downwash angle
System of perpendicular axes used for describing induced velocity distribution. The ~-mxis passes through the centre of the rotor and lies in the plane of symmetry at an angle e 0 (= tan -1 v i o/V) pointing downwards. The T-axis is positive to starboard and ~ positive upwards
Differential application of collective pitch due to trimmer movement. Positive when collective pitch of front rotor is increased
Angular displacement of stick. Positive when forward
Angle of displacement kn pitch of helicopter f rom flight path. Positive when nose up
Collective pitch angle at 0.75R
V sin az) - v~ , coefficient of airflow perpendicular to tip-path plane.
~ R Positive for upward flow through disc
V sin % I - vi coefficient of airflow parallel to no-feathering axis. ~ R
Positive for upward flow through disc
V cos a 9 coefficient of airflow parallel to tip-path plane f~R
21
(82028) B
(
(
¢
¢
~2
)!
)~
)r
)~
)RD
LIST OF SYMBOLS--continued
W - - relative density parameter
2gpsAR
Air density, slugs ft -3
Non-dimensional measure of time
Half swash-plate dihedrak Semi-angle between rotor-hub axes. Positive when axes meet above helicopter
Angle between relative velocity at blade and tip-path plane
Azimuth angle of blade, angle between blade and rearward longitudinal axis
Angular velocity of rotor-hub axis rad/sec
Suffices
Fuselage
Front rotor
Rotor contribution (to be distinguished from fuselage contribution)
Rear rotor
Rear rotor corrected for downwash
22
Ref. No. Author
1 W . Z . Stepniewski . .
2 W. Castles Jnr. and J. H. de Leeuw ..
3 H. Glauert . . . . . . . .
4 H. Heyson and S. Katzoff . . ~ . .
5 J . R . Spreiter and H. A. Sacks . .
6 W. Castles Jnr. and H. L. Durham Jnr.
7 I . C . Cheeseman . . . . . .
8 A . R . S . Bramwell . . . . . .
9 K . B . Amer . . . . . . . .
10 D . F . Gebhard and L. Goland . .
11 Princeton University . . . . . .
12 Bristol Aircraft Ltd . . . . . . .
13 A . R . S . Bramwell . . . . . .
REFERENCES
Title, etc.
A simplified approach to the aerodynamic rotor interference of tandem helicopters.
Paper presented to the West Coast American Helicopter Society, September 21st and 22nd, 1955.
The normal component of the induced velocity in the vicinity of a lifting rotor and some examples of its application.
N.A.C.A. Report 1184.
A general theory of the Autogyro. R. & M. 1111.
Induced velocities near a lifting rotor with non-uniform disc loading.
N.A.C.A. Report 1319.
The rolling up of the trailing vortex sheet and its effect on the downwash behind wings.
Jour. Aero. Sci., Vol. 18, No. 1, January, 1951.
Distribution of normal component in induced velocity in lateral plane of a lifting rotor.
N .A .C .A .T .N . 3841.
A method of calculating the effect of one helicopter rotor upon another.
A.R.C. 20,165. C.P. 406.
Longitudinal stability and control of the single-rotor helicopter.
R. & M. No. 3104.
Theory of helicopter damping in pitch or roll and a com- parison with flight measurements.
N .A .C .A .T .N . 2136.
On the damping in pitch of a helicopter rotor in forward flight.
Jour. Aero. Sci., Vol. 23, No. 11, November, 1956. (Readers' Forum.)
Stability and control of tandem helicopters. Phases I and I I Static and dynamic longitudinal stability and control,
Aeronautical Engineering Department, Report No. 362, September, 1956.
Handling and performance assessment during initial forward flight tests up to flight No. 50.
Type 192--XG. 447. Report FRD]192/5330 C.
Control response measurements on a single-rotor helicopter. (Westland Dragonfly.)
A.R.C. 19,966.
23
(82028) B 2
A P P E N D I X I
Calculation of Rotor Derivatives
The equations for to, al, tz and )~ are
t o = qO o + ceh
a l = caO o + c42~
1,2, = ~ ' C O S ~ D
st c = 12 sin aD 2(tza + aa)lI~"
Differentiating with respect to ~ (i.e. with respect to ~ also)
ate3~ - (Q'O o + c(A) ~u otz + c,. Oka~
aa~a~ _ (ca,00 + q,;~) a/za~ + c~-0}aA
a/, aa~ a~ - cos c¢,) - fl sin ~D a~
~t c s - -
aA _ sin ~D + a cos a n a~ ;~)ll= + a~)al~ / * - + ;~ " a~. 2(/, 2 + 2(/, ~ + ~ ~u]
T h e results of solving these four simultaneous equations are
c2 I sin aD +
~t e
2 ( ~ + a~)~a} + cos ~ . (c,'Oo + ca'a) 1 2(~= + a~)~}
+ ~{c~ (c~'Oo + ~,':~) - ca (cl'Oo + c~'~)}
where
~a 1
A =
ca I sin
1
o~.o +
+
2 ( ~ + a~)~,~} + cos ~ (c3'Oo + q'a) 1 2(~= + a~.)3~ =}
s {ca (c~'Oo + c;a) - q (q'Oo + c;a)}
A
~Stc C2S I
- - ~ c 4 l stanc~ D I I~tc
1 2(/~ + ;~)lte ~ + )~
24
+ /~ tan c~ D (ca'O o + Q'h)} -
(c1'0o+ c2',~)] I •
(75)
(76)
(77)
(78)
(79)
(80)
(81)
(82)
(83)
(84)
(85)
Differentiating equations (75) and (78) with respect to ~ gives
Ote -- (c1'0 o + cz'A) alz Ok
aa~ (c(Oo + c4'k) Ol~ aA a-~ = ~ + c , -~y
aa 1 a~, _ a f~7 cos (% + ~ ) ) = - sin ~ - ~ sin ~ T~
a t e s - -
3A ~a~ 3~ st c ( atz a~ - cos ~9 + I7 sin ~ a~ 2(~ a + A~) 11~ + 2(/z a + A~) ~ta ./z
These equations give
aw} "
(86)
(87)
(88)
(89)
t 5a~st ~ [ . Ast~ 7I ato ~ cos ~ - sin o~ t2 (~ + Aa)~ + (COo + ~;A) 1 2i~a ¥ ~)~ja_/ 0v3 - A (90)
l sin. t l ,tc I c a cos ~D 2 ( ~ + A2)3/~ t - sin ~z)(ca'Oo + ca'A) 1 2(/~ a + Aa)ai2
s sin ~D 2(~a + Aa)l~a {ca (~;0o + q'A) - q (COo + ~(Z)} aal
a~ A
Differentiating equations (75) . . . . (78) with respect to 0 o gives
(91)
Otc _ (q,O ° + c2,A ) atz OA (92) a0 ° ~ + cl + caa0 °
Oa 1 _ (c8,0o + c4,A ) 3/z 3A 00o ~oo + c, + c 4 ~ 0 (93)
at~ I7 sin <o aal ~0o - ~ o (94) at~ $ - -
~a 1 a0 0 st c ( 0/z 0A) - ;7 cos o~ ~0o 20,~ + Aa)~a + 2(~a + ?,a)~ " ~ + A ~ . (95)
aA
a00
These equations give
ll 2(/~ ~ + Aa)ala ) q - l?sin cod [q (ca'Oo + C4'A) -- Ca (q'Oo + C='A)]
' l 19" sin ~jglxsto t ate = - (qc 4 - c2ca) , 17 cos aD -- 2(t~= + Az)3/2} (96)
30 o k
aa 1 _ 2(~2 q~ Az)lta (clca - c2c3) - c8 , 1 2(/~a + Aa)8/a} (97)
300 A
The above derivatives, equations (83), (84), (91), (92), (96) and 97, can also be used for steep descent, except in the vortex ring region where the momentum theory, on which equation (82) is based, breaks down. However, even in this region these derivatives seem to give reasonable values.
25
For level flight good approximations to the derivatives are
~t e O~
£2 l i~st e ! ~ + 2(~. + ~)3r~ + ~ ( ~ (~3'oo + ~ 'h) - q (COo + ~,'h)} +
+ (q'0o + ~'~) 1 - 2(~ + h~W
Oal _ C4 l °~D +
A
t~stc } l Astc 2(tx~ + ,~2)slz + (c8'0o + c~'A) 1 2(~2 + As)st2 + 2(~ + h~p )
(98)
(99)
~t c 00o
£1
A
~t e C 2 ~z A
~ a 1 c 4 ~e =
1 2 ( ~ + ~)3~'~ t ~ (qc~ - c ~ )
C 3
A
l ~stc t .s 1 - 2(tz ~ + A~)s/2 t + 2(tz ~ + ~2)1]2 (clc4 - c2t'3)
~00 A
where the approximation to A is
A = 1 ;~ste c2s + C~/z .
(100)
(101)
(lO2)
(lO3)
(lO4)
26
A P P E N D I X II
Calculaiion of Ra te -o f -Ro l l and Rate -o f -Pi tch Derivat ives
Consider the system of axes in Fig. 6. In the mutually perpendicular set of unit vectors i, j , k,
k is parallel to the rotor-hub axis and i lies in the plane of flapping. Relative to the helicopter th i s
system rotates about k with angular velocity ~. In the other mutually perpendicular set of unit vectors x, y, z, x always is fixed in the blade and y always coincides with j. The x, y, z system
therefore rotates relative to the i, j, k system with angular ve loc i t y - fl about j. Finally since the heli- copter is rolling and pitching about its longitudinal and lateral axes with rates p and q respectively
the angular velocity of the blade can be represented by the vector
A = { f 2 s i n f l - p c o s ~ b c o s ] ~ + qs in~bcosf l}x + {psin~b + q c o s ~ - ~ } y
+ (f~ cos fi - p cos ~ sin fl - q sin ¢ sin fl} z - A~x + Avy + A~z. (105)
The moments of inertia about x, y, z can be taken as 0, I1, 11. Therefore the angular momentum
of the blade is H = I 1 A v y + I i A , z (106)
and the rate of change of angular momentum is
d H OH - + A A H . (107)
dt ~t
Expanding equation (107), and equating the component abou t j to the aerodynamic moment Ma,
gives the flapping equation
M ~ = I 1 {]3 + f22fl - 2pf2 cos ~b + 2qf~ sin ~b}. (108)
The total pitching moment on the helicopter of the rotor forces is
C m = h (t c (a 1 -- B1),+ he} (109) and the rolling moment
C l = h { t o(b 1 + A1) + Cy}. (110)
We have now to calculate re, h o a 1 and b 1 in terms of p and q.
The pitch angle in the tip-path plane is
0 = 00 - a l s i n ¢ + b l c o s ¢ . (111)
The relative wind perpendicular to the blade span (in the sense of increasing incidence) for a
blade element distance x R from the hub is
U v = ~2R (~ - ixao cos ~b + xp sin ~b + xO cos ~b) (112)
where ~ = p/f~ and ~ = q/f2
and along the chord
U r = f~R (/~ sin ~b + x). (113)
The blade incidence is )t - /~a 0 cos ~b + xp sin ~b + xO cos ~b
~ = 0 + ¢ = 0 + b~ sin~b + x
therefore the elementary lift is
d L = ½pac f~R ~ (tz sin ¢ + x) ~ (0 + ¢)dr .
27
(114)
(11s)
Expanding equation (115), taking the mean value round the disc, i.e. with respect to ¢, and integrating between x = 0 and x = B results finally in a thrust coefficient
a {~BO ° (B~ + ~tz ~) + B~h = tzaxB ~ + ½Bt~P} [116) t e =
or in terms of ~/. (A referred to the no-feathering axis which does not change incidence with q)
since
Also, from Fig. 11,
6 / B 3 2 to. = ~ - {~0o (B~ + , ~ ) + m ~ + ½~p)
d H = - d L a o cos ¢ - ( d L ¢ - dD) s in ¢.
Proceeding as above we obtain for the in-plane force coefficient
h~ = -}~3 - -~- aob 1 - ½BF, a o
andtherefore, in terms of )t~,
+ -~-B~aoO - - ½BAa 1 + B A } + 1~Oo2i -
~Btzpa~ + -8-Blxqb ~ + -~-B2Oop
% = ~ l~3h +
+
Calling the lateral forceY have
d Y = - d La o sin ¢ + ( d L ¢ - riD) cos
and in a similar manner to the calculation of C m we have
aBh l 3 ~ bO BZ~/(.~I bO -
_ ~l~aoO ° _ B ^ B B : . 8 1 ~ a l q + ~ B ~ b l p + ~ qOo + ~ h~lbl +
B B ~ B 2
+ 2 I~albl - 3 - a ° P + 3 a°al - /xa°AnS I "
The moment of lift of a blade element about the flapping hinge is
d M A = d L x R .
Equation (123) is integrated' by using equation (115) and M ~ together with the relation
13 = a 0 - a l c o s ¢ - b 1sine,
is substituted in equation (108).
(117)
(118)
(119)
l B 9' a B h 3"2 - -4- ~Oo(B2 + ~ ) (al - BO + ~ B ~ l a l - Y aob~ +
½Bm~o - ~-B2aoO - B ~ / B ~ + ½B~a~ - B ~ / p -
tzOoA~/ - i,~Ooa~ - ~Bl~a lp - ~ B l ~ b ~ -
~ B~Oop - ½ ~ I " (120)
and its coefficient C v (positive in the direction of the retreating blade), we
(121)
(122)
(123)
(124)
28
Equating coefficients of sin ¢ gives
2/*(~B00 + ;~l) 16~ B2p + (125) a , = B "~ - }~," - r B = ( B ~ - ½~,~) B ~ - ½ t " "
Equating coefficients of cos ¢ gives
*B.t*a0 16p B=~ bl - B2 + ½t,2 Y B~ ( B2 + ½t *~) - -B= + ½tz2. (126)
Now C,~ and C~ depend on a 1 and b 1 which in turn depend on ~, therefore the derivatives with respect to ~ must be written
and
l y l g ) r - -
and
ma \ ~ f q / , , ~ = ~-~-q/=a, bl + \ 3al /bl,~ \ aO] + \ Obl ]al, q \ -~q]
{ac,] {acq {acq. {a q {ac,]. {abq % = <T~L,~ = \ ~ A : , b : + \~a:h:,~ <~P] + \ ab:A:,~ \~p]
(127)
(128)
where the suffices indicate those variables kept constant during differentiation. We find on differentiating equations (120), (122), (1i5) and (126) and substituting in (127) and
(.128) that the first and third terms on the right-hand sides of (127) and (128) cancel almost exactly, provided also that the t e rm/ . (A 1 + bl) in (128) is very small, which it should be in tr immed flight.
Thus we have
4ah {~BO o + a-2t - ½l~a~} (129) 2
7 ( B ~ _ ½f,2)
4ah (l~), = - v B ( B 2 + ½l~ ) (§0 o ( B 2 + al~) + ~ B 2 - Bl*al} (130)
Similar expressions, if required, can be obtained for xq and yp but these are usually negligibly small.
It is interesting to note that although the disc incidence changes due to precession when the helicopter is steadily pitching the incidence o£ the no-feathering axis does not change so that there is a corresponding variation of cyclic pitch angle in the tip-path plane which keeps the thrust constant, i.e. zq = 0. This can be inferred from equations (116) and (117).
29
APPENDIX III
Calculation of ~ t~ /~ for a Rotor Fitted with 3a-hinges
The relation between feathering and flapping for a blade attached to a 38-hinge is
( 0 ) , 3 = O o + Cfls . (131) If
~8 = ao - a18 cos ¢ - b18 sin ~ (132)
the feathering in the tip-path plane is
O= 00 + Ca o - C a l s c o s $ - C b l s s i n $ - a l s i n ¢ + blcos~b (133)
and the incidence at a blade element is
A - /~ao cos ¢ = (134) 0 + /~sin~b + x
therefore A - ~ao cos ~I
d T = ½pacf~R ~ (iz sin ~b + x) 2 0 + dx. (135) /zs in~ + x /
Expanding (109), taking the mean value with respect to ~b and integrating between x = 0 and x = B gives a thrust coefficient
(t,)a3 = q (0 o + Cao) + c~A (136)
assuming Cb 18 is small compared with a v By considering the flapping moment equation we obtain
al = c3 (0o + Cao) + q)t (137) and
a 0 1 1 - ~ ( 1 + ~ 2 ) I = l~0o(1 + /z~)+ ½ ( ~ - /~al) I (138)
From (136), (137) and (138) and neglecting some small terms i n / ~ we get
(~to~ ~to (1 Ce~ (i39) °~"" = ~ / + 6e, (1 - ~)
?o where i~N is the thrust derivative without ~a-hinge effect.
30
TABLE 1
Particulars of example helicopter (basically Bristol 173)
Weight 13,000 lb
Rotor radius 25 ft
Rotor speed 26 rad/sec
Solidity 0" 04
hF o.22
h a 0.424
lg + l v 1.62
C.G. range from lp = l~ (fully back) to la - 1~ = 0.1 (IF + l~) (fully forward)
h 1 0" 286
k 2 0" 143
Fuselage drag 300 lb at 100 ft/sec
Moment of inertia in pitch 85,000 slugs ft 2
Lock's inertia number for rotor blade 8
3 0.016
31
TF
\ f51
BI V
~o . H Ri
H O R I Z O N
WEIGHT
FIG. 1. Nomenclature diagram.
X F
r
zF 1 ~v R
l
FIG. 2. Force and moment diagram.
z R
¢ ,
~:~o~ " ~o~.or disc c~ "~tan I V~o~V
. . . . . . . . . . . . . . . . . . . .
FIG. 3. Reference axes for downwash pattern.
32
~ . = 1.07
I
X
v~ o
-0"3 -0- Z - 0 ' I 0 +0.1 ",~ +o.a
~ = ? . 0 7
v> vL o 2
+0.3
I
-3
0
-0 .3 -0.~ -0 . I 0 +0.1 "~ +0.2 +0"3
= 3 . 1 4
I
I
-0.3
FIO. 4.
-0.~ -0.I 0 +o.i ~ +o-~ +0.3
Longitudinal and vertical distribution of mean lateral induced velocity behind front rotor.
33
Stick range -+50 Flight test points from Ref
x 220 r.p.m. + 240 r.p.m. o 260 r.p.m.
12.
-o O
c-
o
° ~
0 - - - i
U
/ . o x+X +
- 2 , t + o X
x
oo~o 4o o
O. # 0 . 2
FIG. 5(a). Comparison of theoretical trim curves with flight test points. (Bristol 192.)
-220 r.p.m.
--240 r.p.m. - -260 r.p.m.
2 "V
t -
O .
O g
/ J
--2 o
FIG. 5(b).
I I o Fl ight tests result= from
Ref. I1.
o
O
O, O
0"1 p. 0.2
Comparison of theoretical trim curves with flight test points. (Helicopter of ref. 11.)
34
STICK MOVEMENT
DEC1.
0
I0
- 5
¢,- eF
~~_~--- - - J - ~ o.o~
-I . 0 . 2 0 ' 3 /U. O'
FIG. 6. Leve l flight t r im curves for 9 = 0°.
= 0
1,5
I0 ,STICK
MOVEMENT oE~.
O
- 5
. . ~ . ~ _ ' ~ F _
/o.os
FIG. 7. Leve l flight t r im curves for ~o = 1 °.
35
~R-ZF ~ = o
20 ~O.OS " ~ 0 " 1
I 0
°//
- I0 0 O.I 0 . 2 O , 3 0 . 4 P
FIG. 8. Level flight t r im curves for 9 = 2 °.
' LR-IF=o j 30 LR+Z ~ ]
i'O ¢
O.I 0 . 2 v- 0 . 3 0 " 4
FIC. 9. Level flight t r im curves for 9 = 3°.
36
,p .',,
^
K . , 4
/ Blade ~ p
1
FIG. 10. Axes used for calculating rate of pitch derivatives.
ao /dC I ~ ~ Plane a l a ¢ ~
- I.. . . . . R
I ~ / I:O
i FIG.I 11. Force diagram for blade element.
×u
XW
- 0 ' 1 5
- 0 . 1
- 0 . 0 5 J J
O 0"1 0 . 2 0 .3 P
FIG. 12. Variation of Xu with F.
0 .4
0"15
0.1 / oos i j
0 0-1 0 2 /, 0 -3
FIG. 13. Variation ofl Xw with F-
0 " 4 I;
i'
OO
0 . 4
0 "2
Zu
O
- 0 . 2
- 0 . 4
1.5
1 .0
Zw
0"5
O
. / . 2
FIG. 14.
/
O.I
J J
,u 0.3 0 , 4
2
'11
o
20
Variation of Z u with F-
/ "-.. /
0"I 0.2
jContribution due tc r o t o r t i l t
0 - 3 # " 0.4
FIG. 16. Variation of damping in pitch, v, with F.
°fie -IO
O.2 0"3 O-. O O-! /z
Variation of Z w with F"
0 ~ l R _ l F 0 . 0 5 -
0-1 IR+ IF
~o=0 °
N
¢p =:~o I
0"2 0"3 0"4
FIG, 15. FIG. 17. Variation of 5f' with F.
o3
Io
0
- I 0
-~O
o £0=0 q0= 3 °
~ / ~ i ,
! [.
. . . . .~ .--"---,,-- o. I [ / o . o s
• 3 ~ " - ~ 0 ¢
FIG. 18. Variation of w with F.
[~+ G
03
IO
-IO
- 2 0 ~ ~ C=0-05
C---O
FIC. 19. Effect of ~-h inge on w,
&-t~_ o) (~o= o,&¥l~ •
39
(82028 C 9.
-15
- i O
- 5
, .~--~F. =0 ' •
i I l 0~1 " o.~ 0.3 t l o~4
FIF. 20. Variation of downwash lag derivative ]~ with /~.
15
Io
o , . 0.! Fie. 21.
I
JR÷ I F = 0'1 . /
+ I F ' -
\ ~ Imm O'a 0.3 // 0.4
Variation of downwash lag derivative X witb V"
i l l
I// / /
4O
~O
,. IO
0 OEC~REES
, 'O
-IO
-SO
• i
' o ~ V v . • . . . .
i m~
! FrG. 22(a). Typical oscillation in hovering (q~ = 1 ° all c.c.
positions. No ~8-hinge).
O.I
_1 °
C .
T" SEC -~
0 . 0 5 J
f
O~ I ~ :~° r.,0
FIG. 22(b). Damping factor of phugoid oscillation in hovering.. (All c.e, positions.) . . . . . . .
I '
3*
4O
To SEC.~
- i * o* I ° ~'* q0 g
Fie. 22(c). Period of phugoid oscillation in hovering. (All C.G. positions.)
e
~ 0 °
15 °
I0 °
(p= I ° t._t~ tR+tF -- 0-05
5 ~
J , . , . . . ,- ,
0 5 10 15 SEe.
FIG. 23(a). Typical time history of longitudinal motion /z = 0.1. ( N o
3a-hinge.)
o , 4 •
0 ' 3
T 5EC - I
0.?_
o . I
i ° ;>=
FIG. 23(b). Damping factor.
[ J
iF+ t-----~ - o 0 " 0 5
" ~ ' ~ = O . I
S °
42
0.4
I0
" ~ = o t . - EF ~o , eR + t F
e
5EC
= 0"05
/ / 5
~o
e
IO
0 tO 5EC. 0
y_io ~ - ~ ~-E; V~ :o.os
/
/ J /
5 I0 SEC.
t_*a
IZR- eF =0 (P = E° {~R + El=
I0 . I0
/ o 40 5EC.
-I0
FIG. 24(a). Typical time histories of longitudinal motion F = 0.2. (No 33-hinge. )
T 5EC.~
0.?..
0
-O'EJ
I00
To SEC.
50
0
01VERGENCE
0 -'0.05 0.I
I °
/ / ~ ° ~
FIG. 24(b). Damping factor.
\
I ° ~° ~o -s °
FIG. 24(c). Period of oscillation.
I - P-R+I~F =0, ,~---'- 0.05
0"I
"~0"I 0-05
0
,.-1~
20 °
o
10 °
0
q~ = o ~ . R - f . F _ P..R + P..F
. . . . .
e/ 5 SECS. IO
IO
0
O
r,o = z ° ~ R - [-F ~-R + £F - - = O "
4 0 SE¢.~.
:o.) 0"2
7' 5EC7 t /
O' l
O
-O - I
D IVERGENCE
- 0 - 0 5
- o q
05CI L L A T I O N
I °
T
" ~ [R + EF
-"- 0.05
a ° c,o a ~
FIG. 25(b). Dampingfactor.
O.1
- - = o
(4)= ~o
Io °
e
.lO °
FIG. 25(a).
eR+ f.F = 0 . 0 5 r..p = e ° - - - - = o . I ~a+ P.F_ i0 °
e
O
• - I 0 '
~ c5.
Typical time histories of longitudinal motion/x = 0.3. (No S~-hinge.)
4O
To SEC. ZO
O
\
I° Z° ~0
Fic. 25(@ Period of oscillation.
--0-1 --0.05 --0
2~
0
4 ~ = 0
0
~R-~F =0.05 l " + ~ r ..
1
S¢C LO
I 0
O
0
- I 0
~ p = 3 °
qf V:
1R- t r _ O . 0 5
IA F I G . 260).
I 0
O
0
- I 0
- I 0
4>= 2 °
0 - 4
ZR-tr = 0 IR + IF
See
r $(~C- I
0 . 2
0
4O
- 0 !2
o 0 U
,,J o
U C
.>_
o lZ
m
o
lR- fr=C ta + tv
FIG. 26(b). Damping factor.
l R + I r :, 4 0
0 0'05 0 0 : 0-
• 2 0 • ~ ~ . .
0 o 2 ° ~ o 3 °
Typical time histories of longitudinal motion /~ = 0"4. (No 33-hinge. )
FIG. 26(c). Period of oscillation.
4 °
0 . 4
0 ' 3
T SEC. - I
0 '1
0
C.~. FULLY
C=O.O5
"~- . . . .~ / c,= o.t
OIVER~ENCE
' (~R-e~ o' ~ACK = k [R ~ eF ,
a ~ s
FIG. 27. Effect of 3~-hinge on damping at/~ = 0.1.
46
0-3
O.I
0 0 .06 0"1 0"15
f~ r. ~o
- 0 . I
q 0 = l °
0.2 ,
FIO. 28.
05CI LLATI(
80
6O
To seas.
40
~0
J j J
0 0 ' 0 5 0'1 0"15 C., 0 ,2
Effect of ~a-hinge on damping and period of longitudinal motion at/z - -0 .2 . (c.G. fully back IR - Iv - 0 ) l ~ + l F "
I 0 0 l ! o
, . " . 0 "3 .... 8 0 '.
0 . 2 " g O
T ~,EC- - I . ~ I V E . R G E N C E
~ \ 40 \ \
o - o s ' - . ~ _ ~ o . , - _ o . , 5 - . o . a . . . . . - - - ~ . . . . . .
- 0 - I ! I , I I c . - ' - 0 " - - 0 - 0 5 0 , 1 . . . . 0 - 1 5 C..,
• ( ) Fie. 29. " Effect of Ss-hingeon damping and period of longitudinal motion at F = 0.3. c.e. fully back lR - lie 0 - l ~ ¥ l ~ , - •
0"~- . . . .
'=' --i
,¢p= a°~
0 . . 2
t" s e c "1
0.1!
0
0.1
i ~ . . . . . . eO
i
2 0
O - O S 0'1 0"15 C 0 " 2 ~ " . "
. . . . . 6 o
T o sec
4 O
O
/
L
~ ~p:=30-"
0 "05
i 0"1 ' 0,15~ C 0 . 2 . . .
FIG. 30. Effect of 33-hinge on damping and period oflongitudinal motion at p = 0"4. C.G. fully back lR T 1F _ _ _ 0 ) i i /
i i
i I ' . '
qO = .0 ° V~, mO'l
1'15
NORMAL ACCELERATION
I'1
I+ '1%
"(:J~ UNITS.
1'05
I 0
/ i
4 +
G 5EC.
C.G. BACK /
C.Gi. FORWARO
ZO
ATTITUDE O DEG$.
I0 J
/
/ / ' /
0 8 4 6 SEC,
0 ?- 4 6 SEC.
CHANGE OF FORWARD SPEED
JJ. FT./SEC.
-gO
FzQ. 31. Response to sudden backward stick dis- placement of 1 °. (/z = 0.1, ~ = 0%)
5O
,/U. ~=O.I
I. 15
NORMAL ACCELERATIOrt
I ' I
I+11. '(}' UNITS
1.05
I
0
= 3 °
C,~. BACK
.-"" C.G. FORWARD
4 6 SEC.
ATTITUOE
e DEGS.
~0
I0 /
/
0 2 4 6 SEC.
0 ~ 4 6 SEC.
CHANGE OF FORWARD SPEED
- g O
FIG. 32. Response to sudden backward stick dis- placement of 1 °. (/z -- 0.1, ~ = 3°.)
51
1'3
NORMAL
ACCELERATI ON 1"8
I + ~
, t UNITS.
9 j /
.G. BACK. I i / C . G . FORWARD :
. . . . /
/ "
O ?. 4 6 SEC.
ATTITUDE e DEr~S.
CHANGE OF FORWARD SPEED
F~/SEC. -~O
~ o I
I0
0 2 - . . . . .
4 6 '~ S E C . !.
4 - , - 6 . ~ ¢ 2 ¢ .
\ \ ' ~ \ ,
FIG. 33.. Response to r sudden backward s t i ck displacement of 1°.!(/~ = O- 2, ~oi= 0%) :
i '
" . . . . . . . , . . . . . L
, , ' . .
!,
• , . . . , . . . .
512
1"3
NORHRL
RCCE L E R RTION I ' g
I + T I ' ~ UNITS.
1 . 1 / f
/°
-C.G. BACK / _ - . - - - -
C.G. FORWARD.
o 4 co SEC. 8
2O
e OEGS. FtTTLTUDE
Io
S
, . f o
. , j o ~ o..~-
f
4 6 5"cc. 8
.It FT./SEC.
- ~ 0 CNRN~E OF
FORWRRD 5P~EO
4 G S~c, 8
FIG. 34. Response to sudden backward stick displacement of 1 °. (F = 0" 2, q~ = 3°.)
:53
(82028) D
1'6
NORMAL ACCELERATION
I + r L '9 ' UNITS
1"4
I'?
I 0
q) = O °
C,.G. BACK
.
/ ° .~._. ~ - - ,C,G. FORWARI:
ZJ 4 6 5EC.
A T T I T U D E 8 DEG.
I0
0
J
/ . / /
/ / -
6 .SEC,
0
CHA~IGE OF
FORWARD SPEED ~U. FT./5EC.
- 2 0
ro 5EC.
\ . \ \
FIG. 35. Response to sudden backward stick displacement of i °. (F = 0.3, qo = 0°.)
54
~,L=0.3 ~ = 3 °
1"6
. I + T L
"9' UNITS.
1.4 IVORtIRL
flCCIELERRTION f 1
0 Z 4
~c.G. BACK
~ - . ~ . . G . FORWARD
B 5EC.
FITTITUDE
e OEr~.
I0
/
0 ~ 4 6 B SEC,
0
1/ FT./SEC.
- ?.0 CHIaNGE OF
FORWFIRD ~PEE D
4 8 ,~EC,
FIG. 36. Response to sudden backward stick displacement of 1 °. (/~ = 0.3, 9 = 3°')
55
(82028) D 2
1'8
I'" 6
NORMAL ACCELERAT lOIN
I + Tt
' 9 ' UNIT5 1"4
I .P
( p - ~
C.G. ~,ACK
/LA = O, 4""
/
/J
i
[ /C.G. FORWARD / / /
/ •
/
0 ? . ' 4 6 8EC.
ATTI TUDE
e DEG.
I0 !
4 8 SEC.
O.
CHANGE OF FORWARD SPEED
~. ~T./SEC. -~0
i 4 8 5EC.
FIG. 37. Response to sudden backward stick displacement of 1 °. (F = 0.4, ~o = 0°.)
56 " i ' Y . , ;,,
} I . = 0 " 4 cp = 3 °
I.G
NORMAL ACCELERATION
I + T L '9' U~,TS
1.4
1.2
I O
IO
ATTITUDE
e oE.~.
O
%'~XC.GBACK
\, C.G. FORWARD
i G SEC.
,! ,[
i
J 2
f
4 6 -SECC 8
0
CHANGE OF FORWARD SPEED
~J. FT2/SEC.
-~O
;4 G 5EC. B
r
%, Fin_,. 38. Response to sudden backward stick . , . :displacement of 1°. (~ ~ 0"4, ~o = 3°.)
o , ,
57
q) = 0 ° C,G. BACK. ~L : O'1
1'15
NORMAL ACCELERAT I DIN
I , I 1 + 1 3 .
~9' UNITS.
I ' 0 5
I O
f / C = O
J . _ J c
4 6 5EC,
C= 0-1
=O-F'
gO ATTITUDE
E) DECk.
IO
O
CHANGE OF FORWARD SPEED
I, IL F .T./SEC.
- 2 0
f
C = O
C 0.1
J C= 0
4 6 SEC.
4 I5 SEC.
"I C=O
I
O.t
FIG. 39. Response to sudden backward stick displacement of 1% (With Sa-hinge. /* = 0.1,
= 0°.)
5 8
~ s . = O ' l Cp = 3 °
1.15
NORi~RL BCCEL ERATION
I'1 I+TL
'9' UNITS
1"05
I 0
j C =
-- '--- C=O.I
~ C = 0.~
4 6 5EC.
RTT1TODE
O DEG.
I0
c=O ~ C =0"1
. , . . _ j C =
0 2 4 6 SEC.
0.~
0 CHRN~E OF
FORWARD ,SPEED
Lt FT./SEC.
-P-O
4 6 '3 EC.
FIG. 40. Response to sudden backward stick displacement of 1 °. (With 33-hinge. F = 0"1,
~ = 3°.)
59
1'3
NGRHRL
RCCELERRTIOM
I + 1 3 .
9' UNITS
-I
I 0
(.p= o ° C.G. BACK
J
~ = o.~.
C = O
/
;~ 4 6
C= I
/ " C= 0 ' ~
8 SEC. )
¢C= 0.1
C = O
J
/ j c 0-~
~0
e DEe, S.
RTTITIIDE .
IO
O~ 2 4 re
Fv/sEc
- S O CH~t#~ OF
FORWRRD .SPEE.D
L
0 • 2 4 6
8 SEC,
8, SEC,
~ '~C=.O. 8 C = O ' I
Fio. 41. Response to~ sudden backward stick displacement of 1 °. (With 33-hinge. p = 0.2,
~o = 0 ° . )
60
o " " " '
~=0.~.. , . C.p = 3 C.G. BACK
I-3
NORMflL
RCCELERflT(ON
I";'
l + T t
~9' UNIT5
I'1 ) I
0
Q
C=O
-~'C = C I
" ~ C = O.~.
8 SEC.
ZO
e OEG.
ATTITIID~
I0
?_
J C = O
J
~ C = O . I
~ ~ ' C= O.;'
4 E, S 5 E C .
o
11 FT./SEC.
- ZO CHFiN~E OF
FORWRRD .~PEED
4 6 B -SEe.
C=O' I C=O
~C-O.~:
FIG. 42. Response to sudden backward stick displacement of 1 °. (With-S3-hinge. /~= 0.2,
~o = 3° . )
61
q:) = 0 ° C.G. SACK /It. =0 "3
1.6
NORMAL ACCELERATION
I ÷ T L • t
9 UNITS 1.4
I . Z ~ ,.
I 0 ?_
/c:o
.C: O.I
C = O .
4 6 SEC.
ATTITUDE
8 DEG. I0
O ? 4
C=O
J J
C=O- I
/ C : O . ?
6 5EC.
O 8 4
CHANGE OF FORWARD 3PEED
,U, FT./SEC.
-~0
6 SEC.
C = O,::',
~C= 0
Z=O.l
FIG. 43. Response to sudden backward stick displacement of 1 °. (With 33-hinge. /~ = 0-3,
~o= 0°.)
62
/./..=0'3 ({) = 3° C.~. BACK
I .~
NORMAL ACCELERATION
I + 1 l '9' UNITS.
1"4
/ f f
~C=O
~ ~ C = O.I C=O'E
O ~ 4 6 8 5EC.
ATTITUDE
e OEG. I0
, ,C=O
C=0.1
• . - - ~ ' - - C = o .a
0 ~ 4 6 B 5EC.
0
CHANGE OF FORWARD 5PEEO
J.l FT./5EC.
- 8 0
Z 4 6 B 5EC.
C=0 'C= 0.1
FIG. 44. Response to sudden backward stick displacement of 1% (With 83-hinge. / z - -0"3 ,
~o = 3°.)
63
q) = O ' C.Ca. B A C K ~ ~0.4, / pC=O
1.8
NORMAL ACCELERATION
I + T ~
~9' UNITS 1'6
1.4
I.Z
J I
O
/ /or
f f
-..---- C : 0.:~
4 6 SEC.
A T T I T U D E
O OEG.
~0
I0
0
f
C=O
C=O.i ~- r
J /
IC=0.£
6 5EC.
CHANGE OF FORWARD .SPEED
JJ. FT./SEC.
-?_O
?- 4 6 SEC.
\ C=O-I
~C= O.~'
FIG. 45. Response to sudden backward Stick displacement of 1% (Wit h S3-hinge. /z:--0.4,
~o 0°.)
/I.=0.4 q) = 3 ° C .G. BACK
1'6 NORMAL
ACCELERATION I + T L
'9' UNITS.
I ' 4 "•C=O
o.I
C
O Z 4 6 5EC. 8
ATT I TUDE ' O DEG.
~'0
I0
f C = O
......--
~C=O'I
--C=O'Z
4 6 SEC. 8
0
/ CHANGE OF FORWARO SPEED
.U. FT./SEC.
- ZO
Z 4 6 SEC. 8
\ c~_ °
Fro. 46. Response to sudden backward stick displacement of I °. (With 6~-hinge. /~ = 0.4,
= 3°.)
~ C = 0 .~
"- C = O-I - -
65
NORMAL ACCELERATION /
/ /
/ . FIG. 47.
TYPICAL RESPONSE OF / TANDEM ROTOR
HELICOPTER WITH NEGATIVE Trtlj.,
SATISF'ACTORY !~ESPONSE
TYPICAL RESPONSE OF SINGLE ROTOR HELICOPTER SATISFYING N.A,C.A. CRITERION
I - T I M E
Comparison of satisfactory response with typical responses of single and tandem-rotor helicopters.
66
1"6
1.5
1.4
1.3
1"2
Cl~C 2
!.1
C 3
1.0
0.9
/c.
1.0
/ c3 ,c4
o.6
0.5 / / 0"8
0.4
0"3
0-7
0"6
0 ' 5 0 0-!
FIG. 48.
0.2
0 0-2 0-3 /~ 0-4 o.5
Variation of the functions q , c~, c 3 and c~ with/~ (B = 0.97).
67
-E:.O
- I . 8
- I . 6
-~1.4
I I C I , C~
- I . 0
- 0 - 8
- 0 . 6
- 0 . 4
- o , ~
O
!,
\
/ //
. . . . . . . . . . . . . . . . . . . . . . . . . . " ~ '8"0
0"1 0'2 0"3 /tJ 0'4
dCl dc2 dc3 "dc4 Variation of ~-cltzdtz,cltx . , =- and ~ with /z (B
I
c I /
2.8
i .
~ '0
? . 6
/ Cla 2 . 4
1.8
F~o. 49.
0 ' 5
C3
\ C : ~
= 0.97).
1.8
1.4
1.2
6s
0'08
0"07 "~ SEC = 0"01
oo~ ~\ ~St c = 0"005
• 0.05 A
0 . 0 4
o.o
0"02 ~
0'01 ~ ""
o
FIG. 50.
0,1 0.~ 0-3 ^ 0"4 V
Var ia t ion of dimensionless induced velocity with ~r
69 (82028} ]~
Part II
The Lateral Stability and Control of the Tandem-Rotor Helicopter
By A. R. S. BRAMWELL
Summary. The lateral stability and control of the tandem-rotor helicopter with a basic configuration similar to that of the Bristol 173 has been investigated. A method of calculating the derivatives is given. Values calculated for the HUP-1 helicopter show fairly good agreement with those obtained from flight measurements.
The stability investigation shows that a tall fin may provide an effective dihedral several times larger than that of the rotors and lead to an unstable Dutch-roll oscillation which becomes progressively worse with increase of speed. The corresponding spiral mode is stable. If the rotors provide the only contribution, the Dutch-roll oscillation is stable but the spiral mode may become unstable.
Simple approximations are given for the. estimation of the damping and period of the stability modes and show quite close approximation to the more exact calculations.
1. Introduction. This Report is the second part of a study of the stability and control of the tandem-rotor helicopter and deals w i t h t h e lateral motion. As in Ref. 2 which dealt with the longi- tudinal behaviour, a configuration similar to that of the Bristol 173 is used as an example.
The equations of motion used in the main part of the Report are referred to wind axes in the usual manner but it is shown that, for the tandem-rotor helicopter, it may be advantageous to refer the equations to the principal inertia axes for lateral stability studies. When these axes are used the
derivatives are easier to calculate and, since product of inertia terms are absent, the terms in the stability quartic are easier to interpret.
The fuselage derivatives have been given special attention since they appear to be at least as
important as the rotor derivatives especially in the case of l v where the fin contribution may be several times that from the rotors.
As in fixed-wing aircraft stability studies, it is possible to obtain simple approximations to the damping and periods of the modes of motion.
2. The Equations of Motion. As usual, wind axes are used, the axes being fixed in the body with
the x-axis directed initially parallel to the t r immed flight path, the y-axis directed to starboard and the z-axis pointing downwards. The equations of motion for small disturbances are then
[/V Wi~ Yv v Y~p + Vr Y~r W ¢ c o s T e - W~bsinTe = Y ~ + Y ~ (1) g g
- L~v + Ap - Lpp - Ei - L,r = L ~ + L¢~ (2)
- N ~ - E p - X ~ p + C t - N~r = N ~ + N d . (3)
Previously issued as R.A.E. Report Naval 4 (A.R.C. 21,918).
70
Dividing equation (1) by 2 p s A ~ 2 R 2 and equations (2) and (3) by 2psA~2Ra and moments of
inertia A and C respectively the non-dimensional forms of the equations of motion become
dr y~v ~2 dr t~' ¢ cos y~ + 1~-- y~ de G - to'~b (4) sin y~ = yCf + y;~
d24 12o d 4 i E d2~ l r d~ f22 l ~ + t'2 I~lv ~ + . . . . . . . . . . . . i x d r z i x d r i x dr ~ i~ dr - i x 7~ l ~ (5)
i o i v d r ~ i c dr + dr ~ i v d r zc n~f + ~ n;~. (6)
The scheme for the conversion of the force and moment derivatives and moments of inertia of equations (1), (2) and (3) to the non-dimensional derivatives and coefficients of inertia of equations (4), (5) and (6) is given in the table of Section 2 of Ref. 1 except that, as in Ref. 2, d is replaced by 2_//.
Solution of equations (4), (5) and (6), when the control terms on the right-hand side are zero, by
the usual substitution ~ = ~0 e~, etc. gives the frequency equation
where A(A'A 4 + B'A a + C'A 2 + D'A + E') = 0 (7)
A ' = 1 zE2 i f ic
+ = + " " /" + ( s ) ze z x z e i~t i o /
C ' = y ~ l , +~_ + ~ _ = + + z c z c z x z x to/ i e z•
+ - ~ - 1 7 - - + ~ - - 1 7 - : (9)
D ' = -Yv \ i a i c z ~
Yr nr Yp , + ~ - ---P 1 7 - + -~ t o cosye + t c sinye
ic ~ ~ + = - - - t~ s i n 7 ~ + cos7~ ZA /~2 i x c
= zx" - t o sin Ye + ic t, cos Ye -- --ic t o sin Ye + ~ to' cos Ye •
The zero root given by equation (7) implies that the aircraft has no preference for a particular heading.
3. The Lateral Stabi l i ty Derivatives. 3.1. The Rotor Derivatives. When a rotor is placed in a
stream of air of velocity V the rotor disc, relative to the no-feathering axis, will tilt backwards with
angle al, and sideways towards the advancing side with angle b r The resukant tilt will be of amount (al 2 + ble) 1;~ and at angle ~b 0 = tan -1 bl/a 1 towards the advancing blade, ¢0 being measured from
71
(82028) • 2
the rear-most position of the blade. I f a small side-wind of velocity v blows from the retreating side of the disc the relative windwi t l appear to come from a new direction at angle e = tan -1 v / V cos a D
in the plane of the disc relative to the original direction. The new sideways flapping component b 1 + 8bl, will be given by
i 1 + 8b 1 = (a l = + ble) 1/2 sin (¢o + e)
= (al 2 q- b12) 1t2 {sin 4'0 cos e + sin e cos ¢o}
therefore
therefore
= b 1 + ale, for small e
alV 8b l = a l e - V cos ~D
~bl al 2(~B00 + h) -~-~ = / , B = + ~/ ,2 (12)
using the familiar expression for ap
It should be noted that the sign O f b 1 for a given direction of tilt depends on the sense of rotation of the rotor and that 8bl/8~ will be of opposite sign if the side-wind blows from the advancing side. However, there will be no confusion if it is remembered that the disc always tilts away from the side-wind.
In addition, a side-wind will also cause a sideways component of the in-plane H-force. This component will be
hcv hoe - V cos ~D
therefore
I ~ Vcos ~D/ t z
~3. (13)
The front and rear rotor contributions to the side-force will then be
a lF + ~8) (Y~)F= - ½ t~F /z
( air + ~a) " (y~)~ = - ½ t~R
These side forces will result in contributions to the moment derivatives
(14)
(15)
(l~)~ = (yv)~,, hl~ + (y~)R hl~ and
From Ref. 2 we find that the side-force contributions due to roll are
(16)
(17)
(y.)~, = - ½ ( t ~
(YD)R = -- ½ ( t c ~
B2a~,~ 16
8 / rB~ (B~ + ~-~)
B~_~) 16 ~B~ (B" + ~ 2 ) -
72
(18)
(19)
The total rotor contributions to the moment due to roll derivatives are therefore
(l;)r = (Yo)P h lF + (Y~)R hlR (20)
(n~)r = (y~)F l l ~ - (Y~)R 11~. (22)
When the tandem-rotor helicopter rotates in yaw side-winds (of opposite signs) will be imposed on the front and rear rotors and we find that
/
(yr)F = - ~t~F l ~ , a~F/~ (22) 1 (Y~)R = + ~to R /1R al R/b*. (23)
The total rotor contributions to the moment due to yaw are then
(l,), = (y,)F hl~ + (Y~)R h~R (24)
(nr)r = (Yr)F 11F -- (Yr)R ll n" (25)
It is useful to note that (y~)~ = (nv) r.
(It is unfortunate that the standard symbols for rate of yaw and suffix for rotor contribution are
the same, namely r. However, when r appears outside a bracket throughout this Report it refers to the contribution of both rotors.)
3.2. Fuse lage D e r i v a t i v e s .
3.2.1. (y~)1
It is difficult to make a theoretical estimate of (Yv)1 but the wind-tunnel tests of Refs. 3 and 9
should give a reasonably accurate value for a typical fuselage. An analysis of these results shows that the fuselage contribution can be represented by
- O. 3 t~S B (Y~)i - s A (26)
3.2.2. (l~) I
The calculation of lo due to a fin is usually of secondary importance for the fixed-wing aircraft
but for the helicopter without a wing the fin contribution to l v may be far greater than that of the rotors and is therefore of great importance.
I f the fin effect is calculated in the manner of Ref. 4 we have
(lv) 1 = - V la /F(oOl2 (27)
where. the interference factor, KFZ~ , of Ref. 4 is taken to be unity.
In the notation of this Report (see Fig. 2) V 1 becomes
Ai VJ = 4 s A
and F(~) = h I cos a s - l] sin %.
a] can be calculated from Ref. 4 but a more accurate value can probably be obtained from Ref. 5. No tandem-rotor helicopter flying at present has a wing but wings may be fitted to future designs.
• The calculation of l~ due to a wing may be calculated from Refs. 4 and 6.
73
Again, we are in difficulty with notation. We would like to use the symbols f o r F to denote the fin contribution to the derivatives but they have already been used to denote-fuselage and front rotor respectively.
However, in lateral stability work, the term 'fin effect' is meant to include all those fuselage effects which act like a fin and so there will be no ambiguity throughout this Report if the suffix f is used to denote the fin contribution.
3.2.3. (n~) s
The method of Ref. 7 has been used for estimating (nv) s but care must be taken to convert the non- dimensional values given there to those which correspond to the tandem-rotor helicopter. Thus the
values of n~B of Ref. 7 must be multiplied by ~SB IB/4sA.R and the values of n ~ v by ~Sb/4sAR. For the fin itself Ref. 7 uses the results of Ref. 5, i.e. the fin contribution, in the notation of this
'Report, will be a s A s I] V/4sA.
3.2.4. The momem derivatives due to rate of roll and rate of yaw. These derivatives, like (lv)s, may be considerable for the helicopter and have been calculated by strip theory, as follows.
Let x be the distance above the centre of area of an elementary strip, parallel to the flight path, of chord C and width dx. A rate of roll p will change the incidence of the strip by p{F(~) + x}/V and the rolling moment of the fin will then be
giving
~_paspR2 fx2 - ~ e { F ( ~ ) + x ? d x (C3s V xl
(l~) s = _ a s & ~ {y~(~) + h~g~} 4sA (28)
where h& is the radius of gyration of the fin about an axis through its centroid parallel to the flight path or, approximately, parallel to the aircraft datum line.
Similarly we derive
( n ~ ) s - as~AslsF(°t) 4sA (29)
(4)s - as~Asl1F(~) 4sA = (np)s (30)
( n r ) 1 = - a f f / A s l l 2 4sA (31)
3.2.5. Control moment derivatives. Adopting the notation for fixed-wing aircraft, an angular displacement of the cyclic stick to port, ~:, produces equal changes of cyclic pitch, kl~: , on front and rear rotors such that both tilt to port. A displacement, ~, of the rudder bar, with the left foot forward, produces tilts, k~, of both rotors, the front rotor tilting to port and the rear rotor to starboard. The control angle notation has been used for stick and rudder displacements rather than the rotor disc displacement because of the possible confusion arising from the signs of the lateral tilt and cyclic pitch application for counter rotating rotors, as mentioned in Section 3.1.
74
In non-dimensional formthe control force and moment derivatives will then be
y¢ = - k~t c' (32)
y~ = - k z ( t c F . - tcR ) (33) '
1~ = - k~ ( t c F h l F + teRh~R ) (34)
l~ = - kz ( t c E h i F - tcRh~R ) (35)
n~ = -- k~ ( t ~ f l ~ F - t, RI~R ) (36)
n; = -- hz ( t~v l~F + t~al~R). (37)
3.3. Compar i son o f Theore t ica l Der i va t i ve s w i th Es t ima tes f r o m F l igh t Tests. The trim equations in level flight for a given steady sideslip angle f i ( ~ / ~ ) are obtained from equations (4), (5) and (6) of Section 2 by omitting the acceleration and rate terms and putting 7~ = o, giving
~/~Yv + to'¢ = - (Yd + Y~) (38)
i~fllv = - ( l ~ + ! ~ ) (39)
~fln~ = - ( n ~ + nc~). (40)
Thus by measuring the control angles (assuming the control derivatives are known from
equations (32) to (37)) and the angle of bank for a given sideslip angle the derivatives Yv, lv and n v can be obtained. A number of such measurements for the Vertol HUP-1 tandem-rotor helicopter is
given in Ref. 8. From these measurements the derivatives were calculated and the results for Yv
and lv; together with the theoretical values are shown in Figs. 3 and 4 where it is seen that the agreement is quite good. On the other hand n v has not been shown as agreement was extremely poor;
it was unfortunate that the fuselage of the HUP-1 is very short and 'stubby' whilst the fin section
has a thickness/chord ratio of 35 per cent and a trailing edge angle of about 45 deg. Thus the
fuselage and fin contributions to n~ were both difficult to estimate accurately and since the total n v is the difference between these comparatively large quantities it is not surprising that the theoretical estimate should be so poor. The estimation of n v for a comparatively slender fuselage, such as that of the Bristol 192 which closely resembles fixed-wing aircraft practice, should be far more reliable.
4. Discussion o f Der iva t ives . The estimated derivatives for the Bristol 173 helicopter are shown in Figs. 5(a) to 5(g). The force-rate derivatives y~ and Yr have been omitted as they are negligibly small.
4.1. Yv
The rotor contribution is roughly proportional to al/tz which is almost constant throughout the speed range. The fuselage contribution which varies linearly with speed is very much larger at all but the lower speeds so that for most of the speed range the rotor contribution can be neglected.
4.2. lv
The rotor contribution is again roughly constant with speed for the reason given above in 4.1. The fin contribution increases rapidly with speed and above/~ = 0.2 is already larger than the rotor
75
contribution. Thus it will be seen that the fin has a powerful dihedral effect compared with that Of the rotors but wi thout a corresponding effect on the damping in roll (Section 4.4). It Will be shown later that this may lead to a very unstable Dutch-roll oscillation at the higher speeds.
It should be noted that, although the force derivative on the fin is linear, the moment derivative rises more rapidly than this since the fin height relativeto the wind-axis increases with the increasing
nose-down attitude in pitch.
4.3. n,v
The rotor contribution is usually negligible and the total n v depends almost entirely on the fuselage and fin contributions. However, it is interesting to note that setting the e.G. forward
increases the front rotor thrust and tilt and decreases the rear rotor thrust and tilt thus causing the rotor contribution to be unstable.
4.4. l~
The rotor provides nearly all the damping in roll, a small contribution arising from the fin at higher speeds. It will be seen later that it would be desirable to be able to increase l~ considerably ~ut presumably this could only be done by fitting a small wing.
4.5. n r
This derivative hardly warrants discussion as it is usually unimportant and, in any case, appears in combination with other derivatives in such a way that its effect can always be eliminated by slight changes in the others.
4.6. lr and n~
These derivatives will be discussed together as their most important effect is their appearance in the constant term, E, of the stability quartic. In level flight E is proportional to lvn ~ - n~l~.
N o w n~ is negative and so is lv, usually, so that the first term contributes to the stability of the spiral mode. On the other hand l r is positive and n v must be positive for positive weathercock stability so that the second term represents spiral instability. However, as can be seen from Figs. 5(f) and
5(g) both l,. and n,. increase With speed, although not necessar!ly in the same ratio, and the effect of one tends to cancel the effect of the other. Therefore the spiral stability depends mainly on the
choice of l~ and n~ being, in any case, easier to control than l r and nr which depend mainly on fin and
rotor heights.
5. Discussion of S t ick -Fixed Stabili ty. 5.1. Approximate Roots of Stabil i ty Quartic. Before discussing the stability in detail, it is worth while obtaining approximations to the roots of equation (7) to see more clearly the dependence of the motions on certain derivatives or combinations of derivatives.
Dividing equation (7) through by A' we obtain
;~ + B;t 8 + CA ~ + D;~ + E = 0. (41)
N o w the coefficient D is always several times larger than E so that to a good approximation one root of equation (41) is h 1 = - E/D. This is the spiral root, familiar also to fixed-wing aircraft practice, and since D is usually positive a stable mode requires that E is als O positive i.e. l,n r - n~l,. > O,
Comparisons between this approximation and more exact calculations are shown in Fig. 8 where agreement is seen to be extremely good.
~6
Dividing equation (41) by (A + E/D) leaves a cubic which can be written approximately as
~3 + BAS + ( C - BE~D) A + D = 0. (42)
• in fixed-wing aircraft practice the coefficient B is large enough (compared with the other coefficients) to take as a good approximation ;~s = - B but this is not always true for the helicopter
as'is shown at the higher values of/z in Fig. 9. Also, Newton's process of approximation which is
often used to obtain a better value of )t s is slowly convergent or may even be divergent at the higher values of tz. However, another iterative process, which seems to work quite well, consists of writing
equation (42) as A s = - {B1 s + (C - B E / D ) h + D} (43)
and substituting ;~ = - B (or a better approximation, if known) into the right-hand side of
equation (43) and taking the cube-root, this latter value being used as the next approximation and the process repeated until the desired accuracy is obtained. This process can be carried out quickly on a slide-rule. Since this root is roughly equal to - B and since B consists very largely of the term l,/i,j, this root can be regarded roughly as representing the damping of the rolling motion. Let c~ be
the value o.f the root obtained from the above process. Dividing equation (42) by (h + ~) leaves a
quadratic ()/s + 13A + y) so that to a good approximation ' ,
(A + E/D) (~ + a) (~2 + 13A + ~,) = ~4 + BA3 + C)tS + D)~ + E.
Equating the constant terms and the terms in A s gives
fl = C/a - D/a s - EID. (neglecting E/D compared with a) (44)
.and (4s)
If we take a B, which is a good approxiniation for t~ < 0.3, then ~, = D/B, an approximation
used in fixed-wing aircraft work giving for the time of oscillation
To = 27r~ %/(B/D) (46) assuming t3 is fairly small.
5.2. Lateral (Dutch ROll) OscillaEon. 5.2.1. Damping of oscillation. The damping of the
lateral oscillation of the complete helicopter is shown in Fig. 6 where it can be seen that the oscillation becomes rapidly unstable with speed. That this is due to excessive dihedral effect is shown by the lower Curves in Which the value of i v used in the calculations is that from the rotors only: T h e beneficial effect of increas!ng l, is shown in Fig. 10 where doubling the existing l , greatly improves the stability. Unfortunately it does not appear possible to increase'/, considerably except by fitting a wing and the only other way of obtaining a damped oscillation is to prevent the fin and
tailplane contributing too much to lv. This might be done by fitting a tailplane which has anhedral or possibly by a retractable fin which, in the extended position, is placed below the aircraft centre
line. We can examine the effect of l . and l o on the damping of the oscillation by referring :to the
expression for ]3, equation (44). Since ~, D and E are almost always positive a damped oscillation can only be achieved if C is positive and the term C/o~ (or approximately C/B) is larger than_the sum
of the other two.
77.
Now numerical calculations show that the coefficients A', B', C', D' and E' of equations (8) to (11) can be written approximately
A' = 1 iE2 • i ~ i ° (47)
B t - - l~O i a ., (48)
C ' = l. Yv + + i~ + (49)
D' - " ~21~z~ t,' ~,2nvio 7Al~° p (50)
e ' = . Ix2. ( l ~ n ~ - n v l ~ ) . (51) ZAI C
The separate terms
C B
D B 2
E D
in ]3 are approximately
_ _ _ \ i ~ "i~ + zo /
< . ,
l#o'i o +'nfl~ l?"
(52)
(53)
(54)
Taking the effect of I, first, all other derivatives remaining constant, the terms in/3 all decrease nr E
with increasing l . except the constant positive term - Yv + ~ ! and the term ~ . Thus as lp
increases 3 tends to the value - Yv + ~ ~ which except, perhaps, at hovering and very low
speeds is positive and increases with speed, i.e. the stability improves.
Turning now to the effect of lv, the most important terms are D/B 2 and the second term of C/B. When l v and l~ are negative and n v positive, i.e. when they represent positive static stability, D/B 2 is positive and contributes to instability of the Dutch roll. This term increases with increase of l v and
usually increases rapidly with speed also. The second term of C/B also contributes to instability /x~l~ i E
increasing rapidly with speed due to the term 7 • -- which becomes negative, as the longitudir/al z~ i e
principal axis assumes a nose-down attitude, and overwhelms the weathercock stability term/x~ nv . zc
Since i E is determined by the mass and fuselage attitude and cannot be varied easily it follows that too large a value of l~, especially at high speeds again leads to instability. These effects ean be seen clearly in Fig. 6. Thus as far as the Dutch roll damping is concerned we wish to make nv as large as
possible and keep /~ and i E as small as possible, assuming iE is positive as is almost certain for a helicopter at all but the lower speeds.
The reduction of damping with increase of i E is often described as a destabilizing 'produet of inertia effect'. This effect is not easy to see physically, compared with those from aerodynamic terms, and in any case the magnitudes of the product of inertia terms depend on the axes chosen.
78
Another interpretation of the term involving i~ can be obtained by writing down the equations of
motion of the helicopter referred to its principal axes. These are given in Appendix 1 where the term
corresponding to • -- + has become - sin ~ + cos ~ . The latter term is \ i x z e z e / z'~ 0 ieo
seen to be the sum of the terms - ~ zl~ and ~n~ resolved about the yawing axis of the wind,axes gA 0 l~U 0
system and therefore represents a kind of weathercock stability--it is not a true weathercock moment since both terms are divided by their corresponding inertias. Nevertheless, it can be seen that when the fuselage takes up a nose-down attitude (negative ~) a negative lo (the usual dihedral
sense) acts partly like a negative weathercock stability and since/~.~l~ is usually several times larger
than/x.~n~ it is quite easy for the whole term to become negative. Thus the deterioration of stability *e
which is often regarded as a 'product of inertia effect' can be interpreted simply as a transformation of the dihedral effect into negative weathercock stability. This interpretation is especially appropriate to a helicopter since the moment derivatives (except those from a wing) are directly related to the t~uselage geometry (and therefore to the principal axes) so that when referred to these axes will be almost independent of attitude. Since helicopter moment derivatives are simpler to calculate when
referred to these axes their use in the study of helicopter lateral stability may be an advantage.
5.2.2. Period of oscillation. Th e approximate expression for the period of lateral oscillation is T O = 27r~ ~/(B/D). This approximation gives good agreement with more exact calculations, except
perhaps at the highest values of/~, as Fig. 7 shows. Using the approximations for B' and D' in
equations (48) and (50) gives
B 1
D - - t~' +/~2n~. l. ~
(55)
The two terms in the denominator are usually of the same order and since both increase with/z the period decreases as/z increases. If a wing is fitted Iv will be much larger and l~ possibly smaller and the time of oscillation would depend almost entirely on n v. The approximation to the time of
oscillation would then be
T o = 2 7 r ~ / [ i° ~ (56) N/ \l~2~nJ
an expression corresponding to one derived for fixed-wing aircraft, Ref. 10.
5.2.3. Dutch Roll-yaw ratio. If l., lv and n~ are varied to improve the damping of the lateral oscillation or perhaps the spiral mode the ratio of amplitudes of roll to yaw in disturbed flight varies also. A simple approximate expression for this "ratio is derived from equations (5) and (6) of Section 2, for zero control movement and neglecting n,,
z~ ~ ~ ~ g) = 0 (57)
= o. (58)
79
i
Now 4 = P = Po e~* and ~ = r = roe ~ where Po and r o are the (complex) amplitudes of the roll and yaw oscillations respectively and A is complex in general: Substituting for ~ and ~ in equations (57) and (58) gives
Oo + zpo l po _ = = 0 ( s 9 )
Eliminating l)o/r o gives
~2n~e0 i E z p 0 + A n~. ic r0 ic r0 ia = 0. (60)
P 0 _ =~- ~ ~ + i~ ~ (61): ro ~2n~(~ ~ ) ~21~iE
ic - + - : - _ _ A ZA ~C
If the coefficient fi of the Dutch-roll quadratic is small compared with 7 then ;~ = - 7 or A = i3, say, equation, (61) becomes
Ix~n~ iE i3 + lr + i~ PO ZG
- . ( 6 2 )
i c ~ + z~ [z c
Inserting typical values into equation (62) shows that many terms can be neglected when the modulus of po/ro is calculated and we have as quite a good approximation
(63) r 0 /~2nv. Iv "
It can be seen from Fig. 11 that the time of oscillation, and therefore 3, does not vary greatly with changes of l~j and l~ so that the Dutch-rolfratio can be said to be roughly proportional to l~ and inversely proportional to n~ and lp. For the Bristol 173 the value of [po/ro [ from equation (63) is 3.75 at/z = 0.2 and agrees well with more exact calculations from an analogue computer.
In fixed-wing aircraft practice a large ratio of roll in yaw is regarded as objectionable. From equation (63) this requires that, for a given 12o , l v should not be too large compared with n~, a combination required also for satisfactory damping of the Dutch-roll oscillation.
5.3. TheSpiralMode. Fig. 8 shows the damping of the spiral mode with /~ for two configurations. Fig. 12 shows the effect of varying l~ and l v on this mode. Since, approximately, A 1 = - E/D we
can infer from the expression for E, what is shown in the Figures, that the larger the value of l v the better the damping of the mode whilst increasing no tends to make the motion divergent. These derivatives have been shown to have the opposite effect on the Dutch-roll damping and, as for fixed-wing aircraft, the choice.of l v an d n.o must often be a compromise between accepting some degree of instability of one or other, or even both, modes. Divergence of the spiral mode does not become very severe even for quite large changes in lo and % and it is usual, in fixed-wing aircraft practice, to accept some spiral instabifity in order to achieve satisfactory d a @ n g of the Dutch roll.
80
6. Control Response. Fig. 14 shows the response of the helicopter to a sudden 1 deg lateral tilt of the rotor discs at/~ = 0.2 for three values of l~. In the original configuration the helicopter is about neutrally stable and reaches maximum bank angle in about 4 seconds and maximum rate of roll in about 1 second. If the stick were held in the displaced position for long enough the helicopter
would roll from side to side with a period of about 8 seconds. If l~ is increased the oscillation becomes stable and the angle of bank reaches a steady value but
the maximum bank angle decreases and the time to reach it increases so that too much damping
in roll for a given l v may cause the aircraft to appear sluggish. If l v is increased for a given value of lp, Fig. 15, we see that the maximum rate of roll is roughly
the same for each case but that the maximum angle of bank is reduced and the time taken to reach it is also reduced. However, if l, is increased too much the lateral oscillation becomes unstable and a steady bank angle is not reached. In these cases the rapid reversal of rate of roll is regarded as undesirable as it may prevent the pilot from banking the aircraft accurately. This effect becomes more pronounced at higher speeds where l v increases and lp falls off slightly.
7. Conclusions. 7.1. A method of calculating the aerodynamic derivatives of a tandem-rotor
helicopter is given and shows fairly good agreement with values obtained from a series of flight
tests.
7.2. The sideslip derivative, l v, is greatly affected by a tall fin which may provide a contribution
several .times larger than that of the rotors.. Since there is no corresponding increase of l•, this leads
to an unstable Dutch-roll oscillation at the higher speeds which becomes progressively worse as
the speed increases. The corresponding spiral mode is stable.
7~3. If the rotors provide the only contribution to l~, the Dutch roll is stable and the stability
improves with speed. The spiral mode becomes unstable at the higher speeds.
7.4. The Dutch-roll characteristics could be improved by fitting a small wing or large tailplane.
This would improve the damping in roll considerably and provide a control over l~. Further, it has been shown that the Dutch-roll stability decreases as the fuselage attitude increases (in the nose-down sense) so that a clean fuselage, resuking in a small attitude, is beneficial. Considering, also, the remarks made in 7.2 it is evident that great care must be taken wKh the design of the fuselage.
• It may be that not all of these requirements can be satisfied together in which case auto-stabilization
may be necessary.
7.5. Simple approximate expressions for the damping and period of the lateral modes can be derived from the coefficients of this quartic and give adequate agreement with more accurate
calculations.
7.6° It may be an advantage to use equations of motion which are referred to the principal inertia axes of the helicopter rather than the wind axes. The coefficients of the stability quartic are no simpler but the derivatives are more closely related to the body axes than the wind axes and generally should be easier to calculate. Also, the product of inertia terms disappear and are replaced by aerodynamic terms which are easier to interpret physically.
81
A
Ao
A
A'
Ai
al
a]
B'
B B bl
b
C
Co C"
C
c,
£
D'
D
E
E'
E
(hlFR).
(hi RR)
ho
hlgR
i o, iao, iE
L I S T OF SYMBOLS
Moment of inertia about longitudinal wind axis, slugs ft ~
Moment of inertia about longitudinal principal axis, slugs ft 2
Area of one rotor disc
Coefficient of M in stability quartic
Fin area, ft ~
Longitudinal backward flapping of rotor disc
Lift slope of fin
Coefficient of ~t 8 in stability quartic
B'/A'
Tip-loss factor (taken as 0.97)
Sideways flapping of rotor disc, positive when tilted to advancing side
Number of rotor blades
Moment of inertia about normal wind axis, slugs ft z
Moment of inertia about normal principal axis, slugs ft s
Coefficient of )¢ in stability quartic
C'IA' Rolling-moment coefficient, rolling moment
2psAlteR 3
Yawing-moment coefficient,
Blade chord, ft
yawing moment 2DsA~R 3
Coefficient of h. in stability quartic
D'/A'
Product of inertia with respect to X and Z axes
Constant term in stability quartic
E'/A'
h 1 c o s % - 11sin%
Height of front rotor above line through e.G. parallel to flight path (see Fig. 1)
Height of rear rotor above line through e.G. parallel to flight path (see Fig. 1)
Coefficient of longitudinal rotor force parallel to tip-path plane
Radius of gyration of fin about axis through e.G. parallel to flight path
A / W Inertia coefficients 0 /~" R~, etc.
82
k 1
k2
L
L~, L , , L~
I ~ R
llRR
. IzR
N
nv, n~, n r
p
P R
T
s~
$
To
t~'
V
Vj 73
W
Y
Y ,Y,,Yr
Y~, Y,, Yr
L I S T OF SYMBOLS--continued
Ratio between lateral stick displacement and cyclic pitch change
Ratio between rudder bar displacement and differential cyclic pitch change
Rolling moment, lb ft
Rolling-moment derivatives, ~L/~v, OL/~p, ~L/~r
Dimensionless rolling-moment derivatives, ~ Cz/~ ~ Ct/~p ~ Ct/~P
Distance of front rotor from c.c. ft (see Fig. 1)
Distance of rear rotor from c.o. ft (see Fig. 1)
Distance between rotors, ft
Length of fuselage, ft
Yawing moment, lb ft
Yawing-moment derivatives ~N/Ov, ~N/~p, ~N/~r
Dimensionless yawing-moment derivatives ~ C~/0~, 0 Cn/Op, ~ CJ ~P
Rate of roll, rad/sec
p/~
Rotor radius, ft
Rate of yaw, rad/sec
Projected side area of fuselage, ft ~
bc Rotor solidity, 7rR
Period of oscillation of Dutch roll
W 2psA~2R 2
Trimmed flight velocity, ft]see
V/nR Fin area ratio, A1/4sA
Lateral velocity of aircraft, ft/sec
vl~R Weight of aircraft, lb
Lateral force, lb
Lateral force derivatives, ~ Y/~v, ~ Y/~p, ~ Y/~r
Dimensionless force derivatives
Value of a root of the stability quartic
83
or D
%
7
~e
0
0 o
/z2
P
¢
¢
t2
]
F
LIST OF SYMBOLS~--continued
Incidence of rotor disc, angle betV~een relative wind and tip-path plane
Incidence of helicopter,-angle between relative wind and datum line
Coefficient of ~ in Dutch roll quadratic ' '
Constant term in Dutch r011 quadratic " -
Angle of climb, radians
Drag coefficient of rotor blade " ~-'
Displacement of rudder bar, positive for negative yawing moment
Angle be tween trimmed flight t~atl~ and undisturbed position of longitudinal principal axis ~':
Angle between horizon and undisturbed, position of longitudinal principal axis
Collective pitch angle of rotor blades, radians
Root of stability quartic
Coefficient of flow normal to rotor disc
Tip speed ratio, V cos ~l)/f2R
Relative density parameter, Vg/2gpsAR
Lateral displacement of stick, positive to port
Air density, slugs/ft 3 ,,
Time in aerodynamic units
Angle of bank, positive to starboard
Angle of yaw, positive to starboard
Angular velocity of rotor -
Suffices
fuselage or fin contribution
front rotor
rear rotor
rotor contribution
84
Ref. No. Author
1 A . R . S . Bramwell ..
2 A . R . S . Bramwell ..
3 C.C. Smith Jr.
4 I. Leva~i4
5 D.J . Lyons and P. L. Bisgood
6 I. Leva~id
7 P . L . Bisgood
8 J .H . Goldberg and R. R. Piper
9 :[. L. Williams ..
10 W. :[. Duncan ..
REFERENCES
Title,. etc.
and control of the single-rotor Longitudinal stability helicopter.
R. & M. 3104.
Longitudinal stability and control of the tandem-rotor helicopter.
Part I of this R. & M.
Static directional stability of tandem-helicopter fuselage. N.A.C.A.R.M. L50F29. T I L 2437.
Rolling moment due to sideslip--Part III. A.R.C. 9987. Unpublished M.o.A. Report.
An analysis of the lift slope of aerofoils of small aspect ratio, including fins, with design charts for aerofoils and control surfaces.
A.R.C. 8540. Unpublished M.o.A. Report.
Rolling moment due to sideslip--Part I. A.R.C. 8709. Unpublished M.o.A. Report.
Notes on the estimation of the yawing derivative due to sideslip.
A.R.C. 9018. Unpublished M.o.A. Report.
Stability and control of tandem helicopters. Phases III and IV. Static and dynamic lateral stability and control.
Princeton University Aeronautical Engineering Department Report No. 395.
Directional stability characteristics of two types of tandem helicopter fuselage models.
N.A.C.A. Tech. Note 3201.
The principles of control and stability of aircraft. Cambridge University Press. 1952.
85
(82028) F
A P P E N D I X
Equations of Motion Referred to Principal Axes
1. Equations of Motion Referred to Principal Axes. T h e equat ions of m o t i o n re fe r red to the
pr inc ipa l iner t ia axes are (see e.g. Ref. 10)
W - - ( 9 - p V s i n t9 + r V c o s tg) = A Y (64) g
Ao~b = AL (65)
Co~ = A N (66)
w h e r e t~ is the angle b e t w e e n the longi tudinal pr incipal axis and the di rect ion of the t r i m m e d fl ight
pa th (posi t ive w h e n the axis is nose-up) , and
A Y = W(~ cos O + ¢ s i n O) + Yv v + Y . p + Yrr + Y ~ + Y ~ (67)
AL = L~v + L . p + L,r + L¢~ + Lg~ (68)
A N = Nvv + N , p + N~r + N ~ + N ~ (69)
w h e r e 0 is the angle b e t w e e n the longi tudinal pr inc ipa l axis and the hor izon (posi t ive w h e n axis
is nose-up) .
I n non -d imens iona l f o r m the equat ions (64) to (66) b e c o m e
d~ ^ y , de 12 sin t$ de y~ d~b + I7 cos ~ ~ - t~'~ cos O d'r yvv P'2 d-r d'r I~ d'r
- t~'~ sin ® = y ~ + y ~ (70)
/~flv e + - - - - = - - - - = - - - = = - ~ - (71) iA o dT~ ~A 0 d~- L,~ o d r z~t 0 zx o
tz~n,~ np d¢ d2¢ n~ d~b _ fxz ng~ + lx~ ng~. (72) ic o i~ o dr + dr ~ i~ o dr iA o Zc=oo
T h e f r equency equa t ion is the quint ic
w h e r e , A(A'A 4 + B'A a + C'A ~ + D'A + E ' ) = 0
A ~ = I
lp n r B ' = - Y v • •
C' = y~ ~ o + -[ff; + \ i a o i c ° i ~ o / ~ o
/z~l~ 12s inv a + + ~ - - 12 cos T
ZA o ~C o
D' [ lp n~ l~ l ; ) ]
+ ~ - 12 c o s ~ - + = - 12 s i n ~ + - t o c o s ® Z.d o $c o
) ( tzenv 1, 12 c o s ~ 9 - Yr l~ 12 s i n ~ + - t c ' s i n @
= = - - t c' cos O - = - - t c s i n ® . _ _ t o' cos O - = = - t c' sin O . Z.d 0 ZC 0 ZC 0 ZA 0 ZA 0
86
2. The Aerodynamic Derivatives with Respect to Principal Axes. The forms of the rotor-moment and fuselage-moment derivatives of Section 3.2 remain the same except that the terms hlF , h 1R,
h v and 11• are replaced by the constant values (h~)F, (h~)±¢, (l~) F and (lp) R respectively in the rotor-moment derivatives and F(~), l 1 and hig are replaced by the constant values (hp)l, (lp) i and (hp)lg in the fuselage derivatives, the suffix D denoting measurements from or along the longitudinal principal axis.
(82028)
87
F 2
T A B L E 1
Particulars of the helicopter, similar to the. Bristol 173, used in th¢ stability calculations
Weight 13,000 lb
Rotor radius 25 ft
Solidity 0.04
Rotor speed 26 rad/sec
h F 0- 2 2
h• 0.424
1F + l R 1.62
h 1 O" 286
k 2 O" 143
d o O" 08
A o (principal moment of inertia in roll) 4,260 slugs ft ~
B o (principal moment of inertia in pitch) 92,500 slugs ft ~
C O (principal moment of inertia in yaw) 89,000 slugs ft z
Longitundial principal axis perpendicular to rotor hub axes when ~ = 0
Lock's inertia number 8
l] 0.72
h/~ 0.126
A t 122 ft ~
a] 1.6
88
t , v _ _ ~ _ / _ i _ ~ s ~ . . . . . . . J_/_l___
FIG. i. Rotor force diagram for lateral stability.
FIG. 2. Diagram defining fin dimensions.
89
0-16
0"!
~Jv
0-0"5
0
/ /
o
/ J
0
/
o
Fio. 3.
O.OB 0"I .].,I, 0"16 0.?.
Comparison of theoretical estimates o f y v with values obtained from flight tests of Ref. 8.
-o ,o3
-O-0?..
.e. v
O
FIG. 4.
- , - . . . . . . - - . . . . . . . .
o . . . J ~ o
ROTOR CONTRIBUTION
J
0.05 0.I 0.15 0,2 # Comparison of theoretical estimates of I v with values
obtained from flight tests of Ref, 8.
90 (
- - ROTOR AklP FUSELAGE . . . . ROTOR OML~(
-0"4.
~v
-0"?'
0 0"1 O.~.
FIC. 5(a).
) "5 )x
p
0.4,
Variation of y~ with/~.
- O . I
£ v
- 0 . 0 5
0
i / o.I o.z ~ k o.s
FIG. 5(b). Variation of/v with/z.
o.¢
+ O - I
"Y'I V
-t-0.05 /
I O'3 0-4.
FIG. 5(c). Variation of n v with/z.
91
-O.I
ROTOR, ROTOR
AND FUSELAGE ONCY
-¢p
-0"05
/
J
O 0-I O'P- .,U. 0-3 0-4-
FIG. 5(d). Variation of I~ with/~.
+0.04
+O.OE
~p
-O.OZ
-O.04
O- I "O °?.... ~ 0-3
~-- ....
/
0.4-
\
\
FIG. 5(e). Variation of np with/z.
92
ROTOR AND FUSELAGE R.OTOR O NL'I"
+0"06
~r
+ 0 - 0 4
+ O-OZ / /
0 0.I 0-~ ~ 0"3 0.4-
FIG. 5(f). Variation of lr with F-
in r
- o . 1 5
-0°I
-0-05 J
O.i 0 -2 ].j. 0 -3 0-4
FZG. 5(g). Variation of n~ with F.
93
0.5
p.SEC "I
- 0 " 5
r" 111
~D
r m
FIG. 6.
EXACT r~ALCULATION . . . . . SIMPLE APPROX.(SEE SECT. 6.1)
/ /
/ /
/ /
/ / TE
//S///DERIVATIVES -
0"1 - - - - ' - ~ O- ?..._. 0-3 O-4-
N
WITH 4, v F R O M - - : : ~ ' ROTORS ONLY \
\ \ \
\
5 - I0
I0 5
O-5
Damping of lateral (Dutch roll) oscillation.
TIME TO DOUBLE AMPLITUDE SEC.
'TIME TO HALVE AMPLITUDE SEC.
15
PERIOD OF OSCILLATION SEC.
IO
WITH "~v FROM ROTORS ONLY
COMpI'ETE DERIVATIVES . ~ ~
o.t 0 . 2 #
/ / /
0-3 0 , 4
FIC. 7. Period of lateral (Dutch roll) oscillation.
94
0-;
0-1
p 5EC " l
-O- I
- O - Z
EXACT CALCULATION E
WITH ~v FROM ROTORS ONLY
O-I 0"2-~"~n 0-3 0 4
COMPLETE. DERIVATIVES i . i
J
< .
\
TIME TO DOUBLE
5 AMPLITUDE SEC.
I10
gO
ZO
IO TIME TO HALVE AMPLITUDE 5EC.
Fro. 8. Damping of spiral mode.
ro
-4-
r SEC - I
-?.
EXACT CALCULATION P = - B
0"I
FIG. 9.
/ COMPLETE DERIVATIVES ,//
<2 . . . . .
14~T14 ~v FROM ROTOR5
O-i # O,3
Damping of rolling mode.
0 .4
TIME TO HALVE AMPLITUDE SEC.
:O'P.
0.3
0"4. "0" 5
1.
,: 95
0.I5
0-1
0.0.~
t' SEC, "1
-0.~
-O'I
--0-15
Ld ..J
Ul z
=,
/ /
/omGmAt. ~ p
/ / t
FIG. 10. Effect of l v and lp on damping of lateral (Dutch roll) oscillation (/x = 0.2).
IO PERIOD OF OSCILLATION
SEC,
5
o
FIG. 11.
~X ORIC~INAL - - ORIr~INAL
X 2X ORI.~INAI,,..E v
Effect Of 1 v and l~ on period of lateral (Dutch roll) oscillation (/z = 0.2).
£p P
96
÷0.0~
r sEcT ~
- 0,0!
- 0 "1
-0"15
z
w
~ . I x ORIGINAL- ~-v
\ \
?-X
~ 3 Y , ORIGINJ
~ x ORIGIN
ORIGINS1.
Fro. 12. Effect of l v and lp on spiral mode (p, = 0" 2).
£v £p
- G
r SEC -I
-4.
_p.
x ORI~INA ~.p
2.% ORIQIN/
. ~ ORIGINI~
.g. P
Lp
...... --.~.ep ~_ ~h/~ L.~,y-
I × ORIGINAL ~, ~ X
FIO. 13. Effect of l v and l~ on damping in roll.
97
30
ORIGINAL DERIVATIVES ~.x ORIGINAL ~.p 3 X ORIGINAL ~,p
ANGLE OF
BANK
~0 DEG.
20
/ /
?- 4. SEC. 6 B
ANGLE OF SIDESLIP /B DEG-
~0
I0
IO
RATE OF YAW
~EG Isac.
4- 5EC. G 8
Fic. 14. Response to 1 ° lateral tilt of rotor discs. Effect of l~ (F = 0.2).
98
30
X ORIGINA L £v - 2 x OR.IGtNAL ~,,p . . . . . . . ORIGINAL "~v- ?-X ORIGINAL, ~,p . . . . . 2 x ORIGINAL .e.v. gX ORIGINAL. &p
~0 ANGLE OF BANK
I0
/ 2
f J
"% ".
\
\
4- SEC.
f
8" IO
ANGLF. OF SIDESLIP /3 OE~.
IO
J
I >.___ L--
",,,.
P- 4 $EC. G O 10
I0
RATE OF .
YAW
f
J
FIG. 15.
2 4. SEc. E, 8 I0
Response to 1 ° lateral tilt of rotor discs. Effect of Z~ (~ = 0.2) .
(82028) Wt. 66/991 K 5 9/61 Hw.
99
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